Methods and compositions for predicting response to eribulin

ABSTRACT

The invention provides methods for predicting the efficacy of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), in the treatment of a subject suffering from breast cancer by determining the level of particular biomarkers in a sample derived from the subject.

RELATED APPLICATIONS

This application is a 35 U.S.C. §371 national stage filing of International Application No. PCT/US2012/029479, filed Mar. 16, 2012, which claims priority to U.S. Provisional Application No. 61/454,426, filed Mar. 18, 2011, the entire contents of each of which are hereby incorporated by reference herein.

BACKGROUND OF THE INVENTION

Cancer is a term used to describe a wide variety of diseases that are each characterized by the uncontrolled growth of a particular type of cell. It begins in a tissue containing such a cell and, if the cancer has not spread to any additional tissues at the time of diagnosis, may be treated by, for example, surgery, radiation, or another type of localized therapy. However, when there is evidence that cancer has metastasized from its tissue of origin, different approaches to treatment are typically used. Indeed, because it is not possible to determine the extent of metastasis, systemic approaches to therapy are usually undertaken when any evidence of spread is detected. These approaches involve the administration of chemotherapeutic drugs that interfere with the growth of rapidly dividing cells, such as cancer cells.

Halichondrin B is a structurally complex, macrocyclic compound that was originally isolated from the marine sponge Halichondria okadai, and subsequently was found in Axinella sp., Phakellia carteri, and Lissodendoryx sp. A total synthesis of halichondrin B was published in 1992 (Aicher et al., J. Am. Chem. Soc. 114:3162-3164, 1992). Halichondrin B has been shown to inhibit tubulin polymerization, microtubule assembly, beta-tubulin crosslinking, GTP and vinblastine binding to tubulin, and tubulin-dependent GTP hydrolysis in vitro. This molecule has also been shown to have anti-cancer properties in vitro and in vivo. Halichondrin B analogs having anti-cancer activities are described in U.S. Pat. No. 6,214,865 B1.

In particular, eribulin mesylate, a Halichondrin B analog, has been developed as an anticancer drug. Recently, eribulin mesylate was approved for the treatment of patients with metastatic breast cancer who have previously received at least two chemotherapeutic regimens for the treatment of metastatic disease, wherein prior therapy may have included an anthracycline and/or a taxane in either the adjuvant or metastatic setting. The ability to predict in advance of treatment whether a cancer patient is likely to be responsive to an anti-cancer agent can guide selection of appropriate treatment, and is beneficial to patients. Accordingly, there is a need for methods for and compositions useful in, assessing or predicting responsiveness to eribulin in patients having cancer and, in particular, breast cancer.

SUMMARY OF THE INVENTION

The invention is based, at least in part, on the observation that a low level of expression, e.g., the absence of expression, of the biomarkers identified herein is indicative of responsiveness to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). Specifically, the absence of expression or a low level of expression of these biomarkers, including, for example, one or more of those biomarkers set forth in Table 1, in a subject is indicative that the subject will be responsive to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate).

Accordingly, in one aspect, the present invention provides a method for determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer, by assaying a sample derived from the subject to determine the level of expression in the sample of a biomarker selected from the group of biomarkers listed in Table 1, wherein a low level of expression of the biomarker is indicative that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), will be effective in treating the subject having breast cancer. In another aspect, the present invention provides a method for determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer, by determining the level of expression of a biomarker selected from the group of biomarkers listed in Table 1 in a sample derived from the subject, wherein a low level of expression of the biomarker is indicative that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), will be effective in treating the subject having breast cancer. In a further aspect, the present invention provides a method for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer, by determining the level of expression of a biomarker selected from the group of biomarkers listed in Table 1 in a sample derived from the subject, and predicting that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), will be effective in treating a subject having breast cancer when there is a low level of expression of the biomarker in the sample. In one embodiment of the foregoing aspects of the invention, the methods may further include obtaining a sample from a subject.

In yet another aspect, the present invention provides a method for determining the sensitivity of a breast tumor, for example, derived from a subject having breast cancer, to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), by determining the level of expression of a biomarker selected from the group of biomarkers listed in Table 1 in the tumor, wherein a low level of expression of the biomarker in the tumor indicates that the tumor is sensitive to treatment with eribulin, or an analog thereof. In yet another aspect, the present invention provides a method for determining the sensitivity of a breast tumor, for example, derived from a subject having breast cancer, to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), by determining the level of expression of a biomarker selected from the group of biomarkers listed in Table 1 in the tumor, and identifying the tumor as being sensitive to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), when the biomarker is expressed in the tumor at a low level.

In further aspects of the invention, methods are provided for treating a subject having breast cancer. The methods include identifying a subject having breast cancer in which a biomarker selected from the group of biomarkers listed in Table 1 is expressed at a low level, and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), to the subject. In yet a further aspect, the present invention provides methods of treating a subject having breast cancer, by assaying a sample derived from the subject to determine the level of expression in the sample of a biomarker selected from the group of biomarkers listed in Table 1, and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), to the subject when a low level of expression of the biomarker is detected in the sample. In one embodiment of the foregoing aspects of the invention, the methods may further include obtaining a sample from a subject.

In further aspects of the invention, methods are provided for treating a subject having breast cancer that is sensitive to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof. The methods include identifying a subject having breast cancer that is sensitive to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, (e.g., a breast cancer in which a biomarker selected from the group of biomarkers listed in Table 1 is expressed at a low level), and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), to the subject. In yet a further aspect, the present invention provides methods of treating a subject having breast cancer that is sensitive to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, by assaying a sample derived from the subject to determine the level of expression in the sample of a biomarker selected from the group of biomarkers listed in Table 1, and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), to the subject when a low level of expression of the biomarker is detected in the sample. In one embodiment of the foregoing aspects of the invention, the methods may further include obtaining a sample from a subject.

In various embodiments, the subject has not been previously treated with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). Alternatively, the subject has been previously treated with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof. In certain embodiments, the breast cancer is an Estrogen Receptor (ER) negative breast cancer and/or a Progesterone Receptor (PR) negative breast cancer and/or a Her-2 negative breast cancer.

In various embodiments, the level of expression of at least 2, at least 3, at least 4 or at least 5 biomarkers selected from the group of biomarkers listed in Table 1 is determined.

In particular embodiments, a predictive gene signature comprising a sub-combination of 2 or more biomarkers selected from the group of biomarkers listed in Table 1 is used. In various embodiments, the level of expression of at least 2, at least 3, at least 4 or at least 5 biomarkers selected from the group of biomarkers listed in Table 1 is determined. For example, the predictive gene signature may include at least 2 biomarkers, e.g., DYSF and EDIL3; GNAT1 and ERGIC3; KRT24 and PAPLN; MANSC1 and PDGFB; PCDH1 and PDGFB; or PHOSPHO2 and PSENEN. In another embodiment, the predictive gene signature may include at least 3 biomarkers, e.g., COL7A1, YTHDF1 and ZIC5; CKLF, IL10 and TUBB6; CDC20, CFL1 and TMEM79; HYAL2, NCBP1 and SNX11; or CEP152, NCBP1 and SATB1. In another embodiment, the predictive gene signature may include at least 4 biomarkers, e.g., APBB2, CCL26, PSENEN and SATB1; ANG, JAM3, KLHL17 and PAPLN; ITFG3, MAD2L1BP, NMU and PDGFB; SPTA1, TYROBP, SNX11 and PSENEN; GRAMD4, GNAT1, TMIGD2 and YTHDF1; or GRAMD4, HYAL2, PHOSPHO2 and TUBB6. In another embodiment, the predictive gene signature may include at least 5 biomarkers, e.g., CCL26, CDC20, ERGIC3, EDIL3 and PCDH1; DYSF, NMU, PHOSPHO2, PSENEN and SNX11; APBB2, CKLF, CYP4F3, TUBB6 and YTHDF1; or CEP152, MAD2L1BP, SPTA1, TMEM79 and ZIC5.

In particular embodiments, the predictive gene signature may include 2 or more of biomarkers ABI3, ANG, APBB2, CCL26, CDC20, CEP152, CFL1, CKLF, COL7A1, CYP4F3, DYSF, GNAT1, GRAMD4, HYAL2, IL10, ITFG3, JAM3, KLHL17, KRT24, MAD2L1BP, MANSC1, MOBKL1B, NCBP1, NMU, PCDH1, PHOSPHO2, SPTA1, TMIGD2, TYROBP, ZIC5, ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1, e.g., ABI3 and ANG; APBB2 and CCL26; GNAT1 and GRAMD4; IL10 and ITFG3; MACSC1 and MOBKL1B; NMU and PCDH1; or TYROBP and ZIC5. In other embodiments, the predictive gene signature includes at least 3 of the previously recited biomarkers, e.g., ABI3, ANG and APBB2; CCL26, CKLF and COL7A1; DYSF, GNAT1 and HYAL2; JAM3, KLHL17 and KRT24; NCBP1, NMU and PCDH1; SPTA1, TMIGD2 and TYROBP; or ZIC5, MAD2L1BP and CDC20. In other embodiments, the predictive gene signature includes at least 4 of the previously recited biomarkers, e.g., ABI3, ANG, APBB2 and CCL26; CEP152, CFL1, CKLF and COL7A1; KRT24, MANSC1, MOBKL1B and SPTA1; TYROBP, TMIGD2, PHOSPHO2 and NMU; ABI3, GNATI, KLHL17 and SPTA1; or CEP152, HYAL2, PCDH1 and TMIGD2. In yet further embodiments, the predictive gene signature includes at least 5 of the previously recited biomarkers, e.g., CKLF, COL7A1, GRAMD4, JAM3 and PCDH1; APBB2, CEP152, DYSF, IL10 and TYROBP; CYP4F3, HYAL2, ITFG3, KLHL17 and KRT24; NCBP1, SPTA1, TMIGD2, IL10 and JAM3; or CCL26, PHOSPHO2, SPTA1, TMIGD2 and ZIC5.

In other embodiments, the predictive gene signature may include 2 or more of biomarkers ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79 or YTHDF1, or any sub-combination thereof, e.g., ERGIC3 and PDGFB; ERGIC3 and PSENEN; ERGIC3 and SATB1; ERGIC3 and SNX11; ERGIC3 and TMEM79; ERGIC3 and YTHDF1; PDGFB and PSENEN; PDGFB and SATB1; PDGFB and SNX11; PDGFB and TMEM79; PDGFB and YTHDF1; PSENEN and SATB1; PSENEN and SNX11; PSENEN and TMEM79; PSENEN and YTHDF1; SATB1 and SNX11; SATB1 and TMEM79; SATB1 and YTHDF1; SNX11 and TMEM79; SNX11 and YTHDF1; or TMEM79 and YTHDF1. In other embodiments, the predictive gene signature includes at least 3 biomarkers, for example, ERGIC3, PDGFB and PSENEN; SATB1, SNX11 and TMEM79; SNX11, TMEM79 and YTHDF1; or ERGIC3, PDGFB and SATB1. In further embodiments, the predictive gene signature includes at least 4 biomarkers, for example, ERGIC3, PDGFB, PSENEN and SATB1; SNX11, TMEM79, YTHDF1 and ERGIC3; or ERGIC3, PDGFB, PSENEN and YTHDF1. In further embodiments, the predictive gene signature includes at least 5 biomarkers, for example, ERGIC3, PDGFB, PSENEN, SATB1 and SNX11; ERGIC3, PDGFB, PSENEN, SATB1 and TMEM79; or PSENEN, SATB1, SNX11, TMEM79 and YTHDF1. In yet further embodiments, the predictive gene signature includes at least 6 biomarkers, for example, ERGIC3, PDGFB, PSENEN, SATB1, SNX11 and TMEM79; PDGFB, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1; or ERGIC3, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1. In yet another embodiment, the predictive gene signature includes 7 biomarkers, for example, ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1.

In various embodiments, the biomarker is not one or more of SPTA1, PAPLN, PCDH1, TMIGD2 and/or KRT24. In a particular embodiment, the biomarker is not SPTA1, PAPLN, PCDH1, TMIGD2 and KRT24. In one embodiment, the biomarker is not SPTA1. In another embodiment, the biomarker is not PAPLN. In another embodiment, the biomarker is not PCDH1. In another embodiment, the biomarker is not TMIGD2. In yet another embodiment, the biomarker is not KRT24.

In particular embodiments, the predictive gene signature may include 2 or more of biomarkers ABI3, ANG, APBB2, CCL26, CDC20, CEP152, CFL1, CKLF, COL7A1, CYP4F3, DYSF, GNAT1, GRAMD4, HYAL2, IL10, ITFG3, JAM3, KLHL17, MAD2L1BP, MANSC1, MOBKL1B, NCBP1, NMU, PHOSPHO2, TYROBP, ZIC5, ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79, YTHDF1, EDIL3 and TUBB6, e.g., ABI3 and ANG; GRAMD4 and HYAL2; NMU and PHOSPHO2; ZIC5 and PSENEN; or SNX11 and MOBKL1B. In other embodiments, the predictive gene signature includes at least 3 of the previously recited biomarkers, e.g., APBB2, CDC20 and CKLF; COL7A1, DYSF and GNAT1; NCBP1, SATB1 and EDIL3; PSENEN, DYSF and GNAT1; MANSC1, ZIC5 and CFL1; or CKLF, GRAMD4 and NMU. In other embodiments, the predictive gene signature includes at least 4 of the previously recited biomarkers, e.g., ANG, CCL26, CEP152 and JAM3; APBB2, CYP4F3, ITFG3 and TYROBP; CYP4F3, MANSC1, PDGFB and YTHDF1; TUBB6, DYSF, PHOSPHO2 and CDC20; or CKLF, KLHL17, HYAL2 and ZIC5. In yet further embodiments, the predictive gene signature includes at least 5 of the previously recited biomarkers, e.g., IL10, CEP152, COL7A1, TYROBP and ERGIC3; TMEM79, SNX11, PSENEN, GNAT1 and GRAMD4; JAM3, SNX11, KLHL17, MOBKL1B and ERGIC3; or NMU, PHOSPHO2, PDGFB, CFL1 and ANG.

In various methods and or kits of the invention, the biomarker is not ABI3, is not ANG, is not APBB2, is not CCL26, is not CDC20, is not CEP152, is not CFL1, is not CKLF, is not COL7A1, is not CYP4F3, is not DYSF, is not GNAT1, is not GRAMD4, is not HYAL2, is not IL10, is not ITFG3, is not JAM3, is not KLHL17, is not KRT24, is not MAD2L1BP, is not MANSC1, is not MOBKL1B, is not NCBP1, is not NMU, is not PCDH1, is not PHOSPHO2, is not SPTA1, is not TMIGD2, is not TYROBP, is not ZIC5, is not ERGIC3, is not PDGFB, is not PSENEN, is not SATB1, is not SNX11, is not TMEM79, is not EDIL3, is not PAPLN, is not TUBB6 and/or is not YTHDF1.

In certain embodiments, the biomarker is not expressed at a detectable level. In another embodiment, the biomarker is expressed at a low level as compared to a control. Expression can be determined directly or indirectly by any suitable method. In certain embodiments, the level of expression of the biomarker is determined at the nucleic acid level using any suitable method. For example, the level of expression of the biomarker can be determined by detecting cDNA, mRNA or DNA. In particular embodiments, the level of expression of the biomarker is determined by using a technique selected from the group consisting of polymerase chain reaction (PCR) amplification reaction, reverse-transcriptase PCR analysis, quantitative reverse-transcriptase PCR analysis, Northern blot analysis, RNAase protection assay, digital RNA detection/quantitation (e.g., nanoString) and combinations or sub-combinations thereof.

In certain embodiments, the level of expression of the biomarker can be determined by detecting miRNA. Specifically, mRNA expression can be assessed indirectly by assessing levels of miRNA, wherein an elevated level of an miRNA which controls the expression of an mRNA is indicative of a low level of expression of the mRNA encoding the biomarker.

In other embodiments, the level of expression of the biomarker is determined at the protein level using any suitable method. For example, the presence or level of the protein can be detected using an antibody or antigen binding fragment thereof, which specifically binds to the protein. In particular embodiments, the antibody or antigen binding fragment thereof is selected from the group consisting of a murine antibody, a human antibody, a humanized antibody, a bispecific antibody, a chimeric antibody, a Fab, Fab′, F(ab′)₂, ScFv, SMIP, affibody, avimer, versabody, nanobody, and a domain antibody, or an antigen binding fragment of any of the foregoing. In particular embodiments, the antibody or antigen binding portion thereof is labeled, for example, with a label selected from the group consisting of a radio-label, a biotin-label, a chromophore-label, a fluorophore-label, and an enzyme-label. In certain embodiments, the level of expression of the biomarker is determined by using a technique selected from the group consisting of an immunoassay, a western blot analysis, a radioimmunoassay, immunofluorimetry, immunoprecipitation, equilibrium dialysis, immunodiffusion, electrochemiluminescence immunoassay (ECLIA), ELISA assay, immunopolymerase chain reaction and combinations or sub-combinations thereof. In particular embodiments, the immunoassay is a solution-based immunoassay selected from the group consisting of electrochemiluminescence, chemiluminescence, fluorogenic chemiluminescence, fluorescence polarization, and time-resolved fluorescence. In other embodiments, the immunoassay is a sandwich immunoassay selected from the group consisting of electrochemiluminescence, chemiluminescence, and fluorogenic chemiluminescence. Other assays which rely on agents capable of detecting the protein, such as those relying upon a suitable binding partner or enzymatic activity, can also be used (e.g., use of a ligand to detect a receptor molecule).

Samples can be obtained from a subject by any suitable method, and may optionally have undergone further processing step(s) (e.g., freezing, fractionation, fixation, guanidine treatment, etc). Any suitable sample derived from a subject can be used, such as any tissue (e.g., biopsy), cell, or fluid, as well as any component thereof, such as a fraction or extract. In various embodiments, the sample is a fluid obtained from the subject, or a component of such a fluid. For example, the fluid can be blood, plasma, serum, sputum, lymph, cystic fluid, nipple aspirate, urine, or fluid collected from a biopsy (e.g., lump biopsy). In other embodiments, the sample is a tissue or component thereof obtained from the subject. For example, the tissue can be tissue obtained from a biopsy (e.g., lump biopsy), breast tissue, connective tissue, and/or lymphatic tissue. In a particular embodiment, the tissue is breast tissue, or a component thereof (e.g., cells collected from the breast tissue). In a particular embodiment, the component of the breast tissue are breast tissue cells. In another embodiment, the component of the breast tissue are circulating breast tumor cells.

In one embodiment, the subject is a human.

In another aspect, the present invention provides a kit for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer, including reagents for determining the level of expression of a biomarker selected from the group of biomarkers listed in Table 1; and instructions for use of the kit to predict whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer. For example, the reagent for determining the level of expression of the biomarker can be a probe for identifying a null mutation in the biomarker. The reagent for determining the level of expression of the biomarker can be a probe for amplifying and/or detecting the biomarker. In yet another embodiment, the reagent for determining the level of expression of the biomarker can be an antibody, for example, an antibody specific for the product of the expression of the wild type or null mutant version of the biomarker.

In a particular embodiment, the kit further includes reagents for obtaining a biological sample from a subject. In another embodiment, the kit includes a control sample.

In another aspect, the present invention provides methods for determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer by determining and/or identifying whether the subject carries at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a null mutation. In another aspect, the present invention provides methods for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer by assaying a sample derived from the subject to determine whether the subject carries at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a null mutation. In a further aspect, the present invention provides methods for determining the sensitivity of a breast tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof by determining and/or identifying whether said tumor is characterized by at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a null mutation. In yet another aspect, the present invention is directed to methods for treating a subject having breast cancer with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof by identifying whether at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a null mutation and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) to the subject.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts the high throughput siRNA screening methods in Breast Cancer Cell Lines performed as described in Example 1.

FIG. 2 depicts the identification and selection of certain genes for further consideration as biomarkers of efficacy of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof.

FIG. 3 depicts the confirmation assays performed as described in Example 1.

FIG. 4 depicts the results of the QuantiTect SYBR Assays to determine the relative quantities of cDNAs after treatment with siRNA as set forth in Example 1.

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides methods for determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer, methods for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer, methods for determining the sensitivity of a breast tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), and methods of treating a subject having breast cancer. Generally, the methods involve determining the level of expression of at least one biomarker as set forth in Table 1 in a sample derived from the subject, wherein a low level of expression of the biomarker is an indication that eribulin, or an analog thereof may be used to treat breast cancer and/or that the breast tumor is sensitive to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate).

The invention is based, at least in part, on the observation that a low level of expression, e.g., the absence of expression, of the biomarkers identified herein is indicative of responsiveness to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). As shown herein, siRNA techniques were employed to “knock down” expression of certain genes and assess the sensitivity of the resulting knock down cells to eribulin mesylate. Based on the findings from these studies, low levels of expression of each of the genes set forth in Table 1 was identified as being associated with the sensitivity of breast cancer cells to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate).

Unless otherwise defined herein, scientific and technical terms used in connection with the present invention shall have the meanings that are commonly understood by those of ordinary skill in the art. The meaning and scope of the terms should be clear, however, in the event of any latent ambiguity, definitions provided herein take precedent over any dictionary or extrinsic definition. Further, unless otherwise required by context, singular terms, for example, those characterized by “a” or “an”, shall include pluralities, e.g., one or more biomarkers. In this application, the use of “or” means “and/or”, unless stated otherwise. Furthermore, the use of the term “including,” as well as other forms of the term, such as “includes” and “included”, is not limiting. Also, terms such as “element” or “component” encompass both elements and components comprising one unit and elements and components that comprise more than one unit unless specifically stated otherwise.

The phrase “determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer” refers to assessing the likelihood that treatment of a subject with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) will be effective (e.g., provide a therapeutic benefit to the subject) or will not be effective in the subject. Assessment of the likelihood that treatment will or will not be effective typically can be performed before treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), has begun or before treatment is resumed. Alternatively or in combination, assessment of the likelihood of efficacious treatment can be performed during treatment, for example, to determine whether treatment should be continued or discontinued. For example, such an assessment can be performed (a) by determining the level of expression of a biomarker, for example, a biomarker selected from the group of biomarkers listed in Table 1, in a sample derived from said subject, wherein a low level of expression of the biomarker indicates that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, may be used to treat said subject having breast cancer, or (b) by assaying a sample derived from said subject to determine the level of expression in said sample of a biomarker, for example, a biomarker selected from the group of biomarkers listed in Table 1, wherein a low level of expression of the biomarker indicates that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, may be used to treat said subject having breast cancer.

The phrase “determining the sensitivity of a breast tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof”, as used herein, is intended to refer to assessing the susceptibility of a breast tumor, e.g., breast cancer cells, to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). Sensitivity of a tumor can include the ability of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), to kill tumor cells, to inhibit the spread and/or metastasis of tumor cells, and/or to inhibit the growth of tumor cells completely or partially (e.g., slow down the growth of tumor cells by at least 5%, 10%, 15%, 20%, 25%, 30%, 35%, 40%, 45%, 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, or 95%). The assessment can be performed (i) before treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), is begun; (ii) before treatment is resumed in the subject; and/or during treatment, for example, to determine whether treatment should be continued or discontinued. For example, such a determination can be performed (a) by determining the level of expression of a biomarker, e.g., a biomarker selected from the group of biomarkers listed in Table 1, in said tumor, wherein a low level of expression of the biomarker in said tumor indicates that said tumor is sensitive to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, or (b) by determining the level of expression of a biomarker e.g., a biomarker selected from the group of biomarkers listed in Table 1, in said tumor, and identifying said tumor as being sensitive to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, when said biomarker is expressed in said tumor at a low level.

The term “eribulin” as used herein refers to the art-recognized fully synthetic macrocyclic ketone analog of halichondrin B. As set forth in U.S. Pat. No. 6,214,865, the entire contents of which are incorporated herein by reference, eribulin has the following structure

and can be generated using techniques as described therein or as described in Kim D S et al. (November 2009) J. Am. Chem. Soc. 131 (43): 15636-41, the entire contents of which are incorporated herein by reference. Eribulin is also known as ER-086526 and is identified by CAS number 253128-41-5. Eribulin mesylate is also known as E7389.

As used herein, the term “eribulin analog” includes compounds in which one or more atoms or functional groups of eribulin have been replaced with different atoms or functional groups. For example, eribulin analogs include compounds having the following formula (I), which also encompasses eribulin:

In formula (I), A is a C₁₋₆ saturated or C₂₋₆ unsaturated hydrocarbon skeleton, the skeleton being unsubstituted or having between 1 and 13 substituents, preferably between 1 and 10 substituents, e.g., at least one substituent selected from cyano, halo, azido, Q₁, and oxo. Each Q₁ is independently selected from OR₁, SR₁, SO₂R₁, OSO₂R₁, NR₂, R₁, NR₂(CO)R₁, NR₂(CO)(CO)R₁, NR₄(CO)NR₂R₁, NR₂(CO)OR₁, (CO)OR₁, O(CO)R₁, (CO)NR₂R₁, and O(CO)NR₂R₁. The number of substituents can be, for example, from 1 to 6, from 1 to 8, from 2 to 5, or from 1 to 4. Throughout the disclosure, numerical ranges are understood to be inclusive.

Each of R₁, R₂, R₄, R₅, and R₆ is independently selected from H, C₁₋₆ alkyl, C₁₋₆ haloalkyl, C₁₋₆ hydroxyalkyl, C₁₋₆ aminoalkyl, C₆₋₁₀ aryl, C₆₋₁₀ haloaryl (e.g., p-fluorophenyl or p-chlorophenyl), C₆₋₁₀ hydroxyaryl, C₁₋₄ alkoxy-C₆ aryl (e.g., C₁₋₃ alkoxy-C₆ aryl, p-methoxyphenyl, 3,4,5-trimethoxyphenyl, p-ethoxyphenyl, or 3,5-diethoxyphenyl), C₆₋₁₀ aryl-C₁₋₆ alkyl (e.g., benzyl or phenethyl), C₁₋₆ alkyl-C₆₋₁₀ aryl, C₆₋₁₀ haloaryl-C₁₋₆ alkyl, C₁₋₆ alkyl-C₆₋₁₀ haloaryl, (C₁₋₃ alkoxy-C₆ aryl)-C₁₋₃ alkyl, C₂₋₉ heterocyclic radical, C₂₋₉ heterocyclic radical-C₁₋₆ alkyl, C₂₋₉ heteroaryl, and C₂₋₉ heteroaryl-C₁₋₆ alkyl. There may be more than one R₁, for example, if A is substituted with two different alkoxy (OR₁) groups such as butoxy and 2-aminoethoxy.

Examples of A include 2,3-dihydroxypropyl, 2-hydroxyethyl, 3-hydroxy-4-perfluorobutyl, 2,4,5-trihydroxypentyl, 3-amino-2-hydroxypropyl, 1,2-dihydroxyethyl, 2,3-dihydroxy-4-perfluorobutyl, 3-cyano-2-hydroxypropyl, 2-amino-1-hydroxy ethyl, 3-azido-2-hydroxypropyl, 3,3-difluoro-2,4-dihydroxybutyl, 2,4-dihydroxybutyl, 2-hydroxy-2(p-fluorophenyl)-ethyl, —CH₂(CO) (substituted or unsubstituted aryl), —CH₂(CO) (alkyl or substituted alkyl, such as haloalkyl or hydroxyalkyl) and 3,3-difluoro-2-hydroxypent-4-enyl.

Examples of Q₁ include —NH(CO)(CO)-(heterocyclic radical or heteroaryl), —OSO₂-(aryl or substituted aryl), —O(CO)NH-(aryl or substituted aryl), aminoalkyl, hydroxyalkyl, —NH(CO)(CO)-(aryl or substituted aryl), —NH(CO)(alkyl)(heteroaryl or heterocyclic radical), O(substituted or unsubstituted alkyl)(substituted or unsubstituted aryl), and —NH(CO)(alkyl)(aryl or substituted aryl).

Each of D and D′ is independently selected from R₃ and OR₃, wherein R₃ is H, C₁₋₃ alkyl, or C₁₋₃ haloalkyl. Examples of D and D′ are methoxy, methyl, ethoxy, and ethyl. In some embodiments, one of D and D′ is H.

The value for n is 1 or preferably 0, thereby forming either a six-membered or five-membered ring. This ring can be unsubstituted or substituted, e.g., where E is R₅ or OR₅, and can be a heterocyclic radical or a cycloalkyl, e.g. where G is S, CH₂, NR₆, or preferably O.

Each of J and J′ is independently H, C₁₋₆ alkoxy, or C₁₋₆ alkyl; or J and J′ taken together are ═CH₂ or —O-(straight or branched C₁₋₅ alkylene)-O—, such as exocyclic methylidene, isopropylidene, methylene, or ethylene.

Q is C₁₋₃ alkyl, and is preferably methyl.

T is ethylene or ethenylene, optionally substituted with (CO)OR₇, where R₇ is H or C₁₋₆ alkyl.

Each of U and U′ is independently H, C₁₋₆ alkoxy, or C₁₋₆ alkyl; or U and U′ taken together are ═CH₂ or —O-(straight or branched C₁₋₅ alkylene)-O—.

X is H or C₁₋₆ alkoxy.

Each of Y and Y′ is independently H or C₁₋₆ alkoxy; or Y and Y′ taken together are ═O, ═CH₂, or —O-(straight or branched C₁₋₅ alkylene)-O—.

Each of Z and Z′ is independently H or C₁₋₆ alkoxy; or Z and Z′ taken together are ═O, ═CH₂, or —O-(straight or branched C₁₋₅ alkylene)-O—.

In certain embodiments, the eribulin analogs include compounds having the following formula (II):

In formula (II), the substitutions are defined as follows:

A is a C₁₋₆ saturated or C₂₋₆ unsaturated hydrocarbon skeleton, said skeleton being unsubstituted or having between 1 and 10 substituents, inclusive, independently selected from cyano, halo, azido, oxo, and Q₁.

Each Q₁ is independently selected from OR₁, SR₁, SO₂R₁, OSO₂R₁, NR₂R₁, NR₂(CO)R₁, NR₂(CO)(CO)R₁, NR₄(CO)NR₂R₁, NR₂(CO)OR₁, (CO)OR₁, O(CO)R₁, (CO)NR₂R₁, and O(CO)NR₂R₁.

Each of R₁, R₂ and R₄ is independently selected from H, C₁₋₆ alkyl, C₁₋₆ haloalkyl, C₁₋₆ hydroxyalkyl, C₁₋₆ aminoalkyl, C₆₋₁₀ aryl, C₆₋₁₀ haloaryl, C₆₋₁₀ hydroxyaryl, C₁₋₃ alkoxy-C₆ aryl, C₆₋₁₀ aryl-C₁₋₆ alkyl, C₁₋₆ alkyl-C₆₋₁₀ aryl, C₆₋₁₀ haloaryl-C₁₋₆ alkyl, C₁₋₆ alkyl-C₆₋₁₀ haloaryl, (C₁₋₃ alkoxy-C₆ aryl)-C₁₋₃ alkyl, C₂₋₉ heterocyclic radical, C₂₋₉ heterocyclic radical-C₁₋₆ alkyl, C₂₋₉ heteroaryl, and C₂₋₉ heteroaryl-C₁₋₆ alkyl.

Each of D and D′ is independently selected from R₃ and OR₃, wherein R₃ is H, C₁₋₃ alkyl, or C₁₋₃ haloalkyl.

n is 0 or 1.

E is R₅ or OR₅, wherein R₅ is independently selected from H, C₁₋₆ alkyl, C₁₋₆ haloalkyl, C₁₋₆ hydroxyalkyl and C₁₋₆ aminoalkyl.

G is O.

Each of J and J′ is independently H, C₁₋₆ alkoxy, or C₁₋₆ alkyl; or J and J′ taken together are ═CH₂.

Q is C₁₋₃ alkyl.

T is ethylene or ethenylene.

Each of U and U′ is independently H, C₁₋₆ alkoxy, or C₁₋₆ alkyl; or U and U′ taken together are ═CH₂.

X is H or C₁₋₆ alkoxy.

Each of Y and Y′ is independently H or C₁₋₆ alkoxy; or Y and Y′ taken together are ═O.

Each of Z and Z′ is independently H or C₁₋₆ alkoxy; or Z and Z′ taken together are ═O.

In some embodiments, the eribulin analogs include compounds having the following formula (III):

wherein A is a C₁₋₆ saturated or C₂₋₆ unsaturated hydrocarbon skeleton, the skeleton being unsubstituted or having between 1 and 13 substituents, e.g., between 1 and 10 substituents selected from cyano, halo, azido, Q₁, and oxo;

each Q₁ is independently selected from OR₁, SR₁, SO₂R₁, OSO₂R₁, NR₂R₁, NR₂(CO)R₁, NR₂(CO)(CO)R₁, NR₄(CO)NR₂R₁, NR₂(CO)OR₁, (CO)OR₁, O(CO)R₁, (CO)NR₂R₁, and O(CO)NR₂R₁; and

each of R₁, R₂, and R₄ is independently selected from H, C₁₋₆ alkyl, C₁₋₆ haloalkyl, C₁₋₆ hydroxyalkyl, C₁₋₆ aminoalkyl, C₆₋₁₀ aryl, C₆₋₁₀ haloaryl, C₆₋₁₀ hydroxyaryl, C₁₋₄ alkoxy-C₆ aryl, C₆₋₁₀ aryl-C₁₋₆ alkyl, C₁₋₆ alkyl-C₆₋₁₀ aryl, C₆₋₁₀ haloaryl-C₁₋₆ alkyl, C₁₋₆ alkyl-C₆₋₁₀ haloaryl, (C₁₋₃ alkoxy-C₆ aryl)-C₁₋₃ alkyl, C₂₋₉ heterocyclic radical, C₂₋₉ heterocyclic radical-C₁₋₆ alkyl, C₂₋₉ heteroaryl, and C₂₋₉ heteroaryl-C₁₋₆ alkyl.

Hydrocarbon skeletons contain carbon and hydrogen atoms and may be linear, branched, or cyclic. Unsaturated hydrocarbons include one, two, three or more C—C double bonds (sp²) or C—C triple bonds (sp). Examples of unsaturated hydrocarbon radicals include ethynyl, 2-propynyl, 1-propenyl, 2-butenyl, 1,3-butadienyl, 2-pentenyl, vinyl (ethenyl), allyl, and isopropenyl. Examples of bivalent unsaturated hydrocarbon radicals include alkenylenes and alkylidenes such as methylidyne, ethylidene, ethylidyne, vinylidene, and isopropylidene. In general, compounds of the invention have hydrocarbon skeletons (“A” in formula (I)) that are substituted, e.g., with hydroxy, amino, cyano, azido, heteroaryl, aryl, and other moieties described herein. Hydrocarbon skeletons may have two geminal hydrogen atoms replaced with oxo, a bivalent carbonyl oxygen atom (═O), or a ring-forming substituent, such as —O-(straight or branched alkylene or alkylidene)-O— to form an acetal or ketal.

C₁₋₆ alkyl includes linear, branched, and cyclic hydrocarbons, such as methyl, ethyl, propyl, isopropyl, butyl, isobutyl, sec-butyl, tert-butyl, pentyl, isopentyl, sec-pentyl, neo-pentyl, tert-pentyl, cyclopentyl, hexyl, isohexyl, sec-hexyl, cyclohexyl, 2-methylpentyl, tert-hexyl, 2,3-dimethylbutyl, 3,3-dimethylbutyl, 1,3-dimethylbutyl, and 2,3-dimethyl but-2-yl. Alkoxy (—OR), alkylthio (—SR), and other alkyl-derived moieties (substituted, unsaturated, or bivalent) are analogous to alkyl groups (R). Alkyl groups, and alkyl-derived groups such as the representative alkoxy, haloalkyl, hydroxyalkyl, alkenyl, alkylidene, and alkylene groups, can be C₂₋₆, C₃₋₆, C₁₋₃, or C₂₋₄.

Alkyls substituted with halo, hydroxy, amino, cyano, azido, and so on can have 1, 2, 3, 4, 5 or more substituents, which are independently selected (may or may not be the same) and may or may not be on the same carbon atom. For example, haloalkyls are alkyl groups with at least one substituent selected from fluoro, chloro, bromo, and iodo. Haloalkyls may have two or more halo substituents which may or may not be the same halogen and may or may not be on the same carbon atom. Examples include chloromethyl, periodomethyl, 3,3-dichloropropyl, 1,3-difluorobutyl, and 1-bromo-2-chloropropyl.

Heterocyclic radicals and heteroaryls include furyl, pyranyl, isobenzofuranyl, chromenyl, xanthenyl, phenoxathienyl, 2H-pyrrolyl, pyrrolyl, imidazolyl (e.g., 1-, 2- or 4-imidazolyl), pyrazolyl, isothiazolyl, isoxazolyl, pyridyl (e.g., 1-, 2-, or 3-pyridyl), pyrazinyl, pyrimidinyl, pyridazinyl, indolizinyl, isoindolyl, 3H-indolyl, indolyl (e.g., 1-, 2-, or 3-indolyl), indazolyl, purinyl, 4H-quinolizinyl, isoquinolyl, quinolyl, phthalazinyl, naphthyridinyl, quinoxalinyl, quinazolinyl, cinnolinyl, pteridinyl, pyrrolinyl, pyrrolidinyl, imidazolidinyl, pyrazolidinyl, pyrazolinyl, piperidyl, piperazinyl, indolinyl, isoindolinyl, and morpholinyl. Heterocyclic radicals and heteroaryls may be linked to the rest of the molecule at any position along the ring. Heterocyclic radicals and heteroaryls can be C₂₋₉, or smaller, such as C₃₋₆, C₂₋₅, or C₃₋₇.

Aryl groups include phenyl, benzyl, naphthyl, tolyl, mesityl, xylyl, and cumenyl.

It is understood that “heterocyclic radical”, “aryl”, and “heteroaryl” include those having 1, 2, 3, 4, or more substituents independently selected from lower alkyl, lower alkoxy, amino, halo, cyano, nitro, azido, and hydroxyl. Heterocyclic radicals, heteroaryls, and aryls may also be bivalent substituents of hydrocarbon skeleton “A” in formula (I).

The term “eribulin analog” includes eribulin prodrugs. The term “eribulin prodrugs” includes eribulin that has been chemically modified to be inactive or less active until bioactivation (e.g., metabolism in vivo) by an enzyme which cleaves the chemically modified portion of the eribulin prodrug, thereby providing the active form of eribulin.

As used herein, the term “eribulin analog” includes all stereoisomers of eribulin and other compounds of formula (I), including diastereoisomers and enantiomers thereof “Stereoisomers” refers to isomers that differ only in the arrangement of the atoms in space. “Diastereoisomers” refers to stereoisomers that are not mirror images of each other. “Enantiomers” refers to stereoisomers that are non-superimposable mirror images of one another. For example, Formula (IV) encompasses eribulin and such stereoisomers:

The phrase “pharmaceutically acceptable salt,” as used herein, is a salt formed from an acid and a basic nitrogen group of Eribulin or an eribulin analog. Examples of such salts include acid addition salts and base addition salts, such as inorganic acid salts or organic acid salts (e.g., hydrochloric acid salt, sulfuric acid salt, citrate, hydrobromic acid salt, hydroiodic acid salt, nitric acid salt, bisulfate, phosphoric acid salt, super phosphoric acid salt, isonicotinic acid salt, acetic acid salt, lactic acid salt, salicylic acid salt, tartaric acid salt, pantothenic acid salt, ascorbic acid salt, succinic acid salt, maleic acid salt, fumaric acid salt, gluconic acid salt, saccharinic acid salt, formic acid salt, benzoic acid salt, glutaminic acid salt, methanesulfonic acid salt, ethanesulfonic acid salt, benzenesulfonic acid salt, p-toluenesulfonic acid salt, pamoic acid salt (pamoate)), as well as salts of aluminum, calcium, lithium, magnesium, calcium, sodium, zinc, and diethanolamine. It will be understood that reference to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, includes pharmaceutically acceptable salts of eribulin as well as pharmaceutically acceptable salts of an analog thereof. Examples of such pharmaceutically acceptable salts include, but are not limited to, a pharmaceutically acceptable salt of Formula I, a pharmaceutically acceptable salt of Formula II, a pharmaceutically acceptable salt of Formula III or a pharmaceutically acceptable salt of Formula IV.

In a particular embodiment, eribulin mesylate, a pharmaceutically acceptable salt form of eribulin is utilized in the methods of the present invention. Eribulin mesylate is sold under the trade name HALAVEN®. The chemical name for eribulin mesylate is 11,15:18,21:24,28-Triepoxy-7,9-ethano-12,15-methano-9H,15H-furo[3,2-i]furo[2′,3′:5,6]pyrano[4,3-b][1,4]dioxacyclopentacosin-5(4H)-one, 2-[(2S)-3-amino-2-hydroxypropyl]hexacosahydro-3-methoxy-26-methyl-20,27-bis(methylene)-, (2R,3R,3aS,7R,8aS,9S,10aR,11S,12R,13aR,13bS,15S,18S,21S,24S,26R,28R,29aS)-methanesulfonate (salt). Eribulin mesylate has the following structure

Eribulin mesylate is label indicated for the treatment of patients with metastatic breast cancer who have previously received at least two chemotherapeutic regimens for the treatment of metastatic disease, including, for example, therapy with an anthracycline and a taxane in either the adjuvant or metastatic setting.

As used herein, the term “biomarker” is intended to encompass a substance that is used as an indicator of a biologic state and includes for example, genes (or portions thereof), mRNAs (or portions thereof), miRNAs (microRNAs), and proteins (or portions thereof). A “biomarker expression pattern” is intended to refer to a quantitative or qualitative summary of the expression of one or more biomarkers in a subject, such as in comparison to a standard or a control.

Various biomarkers which can be used in the methods described herein are summarized in Table 1. Table 1 provides gene abbreviations, Gene ID numbers and accession numbers for transcripts from which encoding nucleotide gene sequences can be identified. For example, gene ABI3 refers to a Homo sapiens ABI family, member 3. The nucleotide sequence for human ABI3 transcript variant 1 can be found at Accession Number NM_016428. Reference to a gene (e.g., ABI3) is intended to encompass naturally occurring or endogenous versions of the gene, including wild type, polymorphic or allelic variants or mutants (e.g., germline mutation, somatic mutation) of the gene, which can be found in a subject and/or tumor from a subject. In some embodiments, the sequence of the biomarker gene is at least about 80%, at least about 85%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, or at least about 99% identical to a sequence identified in Table 1 by Accession Number or Gene_ID number. For example, sequence identity can be determined by comparing sequences using NCBI BLAST (e.g., Megablast with default parameters).

As used herein, the phrase “predictive gene signature” refers to expression levels of two or more biomarkers of the present invention in a subject that are indicative of responsiveness to treatment with eribulin, or an eribulin analog. For example, the low level expression of at least 2, at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9 or at least 10 biomarkers from Table 1 in a subject may constitute a gene signature that indicates that the subject will respond positively to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). Any sub-combination of 2 or more markers from Table 1 may constitute a predictive gene signature of the invention. In another example, the expression of at least 1, at least 2, at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9 or at least 10 biomarkers from Table 1 under particular threshold levels, or any sub-combination thereof, constitutes a gene signature that indicates that the subject will respond positively to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate).

A “low level of expression” of the biomarker, for example, a biomarker selected from the group of biomarkers listed in Table 1, refers to a level of expression of the biomarker in a test sample (e.g., a sample derived from a subject) that correlates with sensitivity to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). This can be determined by comparing the level of expression of the biomarker in the test sample with that of a suitable control. A “low level of expression” also includes a lack of detectable expression of the biomarker.

In some embodiments, the level of expression of the biomarker is determined relative to a control sample, such as the level of expression of the biomarker in normal tissue (e.g., a range determined from the levels of expression of the biomarker observed in normal tissue samples). In these embodiments, a low level of expression will fall below or within the lower levels of this range. In some embodiments, the level of expression of the biomarker is determined relative to a control sample, such as the level of expression of the biomarker in samples (e.g., tumor samples, circulating tumor cells) from other subjects. For example, the level of expression of the biomarker in samples from other subjects can be determined to define levels of expression which correlate with sensitivity to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), and the level of expression of the biomarker in the sample from the subject of interest is compared to these levels of expression, wherein a comparable or lower level of expression in the sample from the subject is indicative of a “low level of expression” of the biomarker in the sample. In another example, the level of expression of the biomarker in samples (e.g., tumor samples, circulating tumor cells) from other subjects can be determined to define levels of expression which correlate with resistance or non-responsiveness to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), and the level of expression of the biomarker in the sample from the subject of interest is compared to these levels of expression, wherein a lower level of expression in the sample from the subject is indicative of a “low level of expression” of the biomarker in the sample.

The term “known standard level” or “control level” can refer to an accepted or pre-determined expression level of the biomarker, for example, a biomarker selected from the group of biomarkers listed in Table 1 which is used to compare expression level of the biomarker in a sample derived from a subject. In one embodiment, the control expression level of the biomarker is the average expression level of the biomarker in samples derived from a population of subjects. For example, the control expression level can be the average expression level of the biomarker in breast cancer cells derived from a population of subjects with breast cancer. The population may be subjects who have not responded to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), or the population may be a group of subjects who express the respective biomarker at high or normal levels. In some embodiments, the control level may constitute a range of expression of the biomarker in normal tissue, as described above. For example, the control level may constitute a range of expression of the biomarker in tumor samples from a variety of subjects having breast cancer, as described above.

As further information becomes available as a result of routine performance of the methods described herein, population-average values for “control” level of expression of the biomarkers of the present invention may be used. In other embodiments, the “control” level of expression of the biomarkers may be determined by determining expression level of the respective biomarker in a subject sample obtained from a subject before the suspected onset of breast cancer in the subject, from archived subject samples, and the like.

Control levels of expression of biomarkers of the invention may be available from publicly available databases. In addition, Universal Reference Total RNA (Clontech Laboratories) and Universal Human Reference RNA (Stratagene) and the like can be used as controls. For example, qPCR can be used to determine the level of expression of a biomarker, and an increase in the number of cycles needed to detect expression of a biomarker in a sample from a subject, relative to the number of cycles needed for detection using such a control, is indicative of a low level of expression of the biomarker.

As used herein, the term “subject” or “patient” refers to human and non-human animals, e.g., veterinary patients. The term “non-human animal” includes vertebrates, e.g., mammals, such as non-human primates, mice, rabbits, sheep, dog, cat, horse, cow, or other rodent, ovine, canine, feline, equine or bovine species. In one embodiment, the subject is a human.

The term “sample” as used herein refers to cells, tissues or fluids isolated from a subject, as well as cells, tissues or fluids present within a subject. The term “sample” includes any body fluid (e.g., blood, lymph, cystic fluid, nipple aspirates, urine and fluids collected from a biopsy (e.g., lump biopsy)), tissue or a cell or collection of cells from a subject, as well as any component thereof, such as a fraction or extract. In one embodiment, the tissue or cell is removed from the subject. In another embodiment, the tissue or cell is present within the subject. Other samples include tears, plasma, serum, cerebrospinal fluid, feces, sputum and cell extracts. In one embodiment, the sample contains protein (e.g., proteins or peptides) from the subject. In another embodiment, the sample contains RNA (e.g., mRNA molecules) from the subject or DNA (e.g., genomic DNA molecules) from the subject.

As used herein, the term “breast cancer” refers generally to the uncontrolled growth of breast tissue and, more specifically, to a condition characterized by anomalous rapid proliferation of abnormal cells in one or both breasts of a subject. The abnormal cells often are referred to as malignant or “neoplastic cells,” which are transformed cells that can form a solid tumor. The term “tumor” refers to an abnormal mass or population of cells (i.e., two or more cells) that result from excessive or abnormal cell division, whether malignant or benign, and pre-cancerous and cancerous cells. Malignant tumors are distinguished from benign growths or tumors in that, in addition to uncontrolled cellular proliferation, they can invade surrounding tissues and can metastasize. In breast cancer, neoplastic cells may be identified in one or both breasts only and not in another tissue or organ, in one or both breasts and one or more adjacent tissues or organs (e.g. lymph node), or in a breast and one or more non-adjacent tissues or organs to which the breast cancer cells have metastasized.

Eribulin, an analog thereof, or pharmaceutically acceptable salt thereof, can be used to treat breast cancer, and, accordingly, the methods of the present invention can be used in breast cancer and in subjects having breast cancer.

In one embodiment, the breast cancer is Estrogen Receptor (ER) negative breast cancer, Progesterone Receptor (PR) negative breast cancer and/or HER-2 negative breast cancer. For example, the breast cancer may be Estrogen Receptor (ER) negative and Progesterone Receptor (PR) negative breast cancer; Estrogen Receptor (ER) negative and HER-2 negative breast cancer; Progesterone Receptor (PR) negative and HER-2 negative breast cancer; or Estrogen Receptor (ER) negative breast cancer, Progesterone Receptor (PR) negative breast cancer and HER-2 negative (triple negative) breast cancer. Assessment of ER, PR and HER-2 status can be done using any suitable method. For example, HER-2 status can be assessed by immunohistochemistry (IHC) and/or gene amplification by fluorescence in situ hybridization (FISH), for example, according to National Comprehensive Cancer Network [NCCN] guidelines.

The breast cancer can be for example, adenocarcinoma, inflammatory breast cancer, recurrent (e.g., locally recurrent) and/or metastatic breast cancer. In some embodiments, the breast cancer is endocrine refractory or hormone refractory. The terms “endocrine refractory” and “hormone refractory” refer to a cancer that is resistant to treatment with hormone therapy for breast cancer, e.g., aromatase inhibitors or tamoxifen. Breast cancers arise most commonly in the lining of the milk ducts of the breast (ductal carcinoma), or in the lobules where breast milk is produced (lobular carcinoma). Accordingly, in various embodiments of the invention, the breast cancer can be ductal carcinoma or lobular carcinoma. Cancerous cells from the breast(s) may invade or metastasize to any other organ or tissue of the body. For example, cancer cells often invade lymph node cells and/or metastasize to the liver, brain and/or bone.

In various embodiments of the present invention, the subject may be suffering from Stage I, Stage II, Stage III or Stage IV breast cancer. The stage of a breast cancer can be classified as a range of stages from Stage 0 to Stage IV based on its size and the extent to which it has spread. The following table summarizes the stages, which are well known to clinicians:

LYMPH NODE METASTASIS STAGE TUMOR SIZE INVOLVEMENT (SPREAD) I Less than 2 cm No No II Between 2-5 cm No or in same side of breast No III More than 5 cm Yes, on same side of breast No IV Not applicable Not applicable Yes

Various aspects of the invention are described in further detail in the following subsections.

I. Prediction of Responsiveness to Eribulin, an Analog Thereof, or a Pharmaceutically Acceptable Salt Thereof (e.g., Eribulin Mesylate) in Subjects with Breast Cancer

In one aspect, the invention provides a method for determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer and/or for determining the sensitivity of a breast tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). The methods involve determining the expression level of at least one biomarker, for example, by assaying a sample derived from a subject having breast cancer. The identification of low levels of expression of at least one biomarker is indicative that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) may be used for treatment of the breast cancer and/or that the breast tumor is sensitive to the treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate).

In the methods of the invention, the expression level of at least one biomarker selected from the group of biomarkers set forth in Table 1 is assessed, which, as explained herein, can comprise determining the level of expression of one or more of these genes (e.g., ABI3, ANG) using various approaches, such as determining in a suitable sample the presence of certain DNA polymorphisms or null mutations, determining the level of RNA expressed from a gene, including an mRNA exemplified in Table 1 and/or other transcripts from the gene, or a protein product(s) of any of the foregoing.

TABLE 1 BIOMARKERS OF RESPONSIVENESS TO ERIBULIN, AN ANALOG THEREOF, OR A PHARMACEUTICALLY ACCEPTABLE SALT THEREOF (e.g., ERIBULIN MESYLATE) GENE ACCESSION SEQ ID NAME GENE_ID NO. NO: NAME ABI3 51225 NM_016428 1 & 2 Homo sapiens ABI family, member 3 (ABI3), transcript variant 1, mRNA ANG 283 NM_001097577 3 & 4 Homo sapiens angiogenin, ribonuclease, RNase A family, 5 (ANG), transcript variant 2, mRNA APBB2 323 NM_173075 5 & 6 Homo sapiens amyloid beta (A4) precursor protein-binding, family B, member 2 (APBB2), mRNA CCL26 10344 NM_006072 7 & 8 Homo sapiens chemokine (C-C motif) ligand 26 (CCL26), mRNA CDC20 991 NM_001255  9 & 10 Homo sapiens cell division cycle 20 homolog (S. cerevisiae) (CDC20), mRNA CEP152 22995 NM_014985 11 & 12 Homo sapiens centrosomal protein 152 kDa (CEP152), mRNA CFL1 1072 NM_005507 13 & 14 Homo sapiens cofilin 1 (non-muscle) (CFL1), mRNA CKLF 51192 NM_016326 15 & 16 Homo sapiens chemokine-like factor (CKLF), transcript variant 3, mRNA COL7A1 1294 NM_000094 17 & 18 Homo sapiens collagen, type VII, alpha 1 (COL7A1), mRNA CYP4F3 4051 NM_000896 19 & 20 Homo sapiens cytochrome P450, family 4, subfamily F, polypeptide 3 (CYP4F3), mRNA DYSF 8291 NM_003494 21 & 22 Homo sapiens dysferlin, limb girdle muscular dystrophy 2B (autosomal recessive) (DYSF), transcript variant 8, mRNA EDIL3 10085 NM_005711 23 & 24 Homo sapiens EGF-like repeats and discoidin I-like domains 3 (EDIL3), mRNA ERGIC3 51614 NM_015966 25 & 26 Homo sapiens ERGIC and golgi 3 (ERGIC3), transcript variant 2, mRNA GNAT1 2779 NM_000172 27 & 28 Homo sapiens guanine nucleotide binding protein (G protein), alpha transducing activity polypeptide 1 (GNAT1), transcript variant 2, mRNA GRAMD4 23151 NM_015124 29 & 30 Homo sapiens GRAM domain containing 4 (GRAMD4), mRNA HYAL2 8692 NM_003773 31 & 32 Homo sapiens hyaluronoglucosaminidase 2 (HYAL2), transcript variant 1, mRNA IL10 3586 NM_000572 33 & 34 Homo sapiens interleukin 10 (IL10), mRNA ITFG3 83986 NM_032039 35 & 36 Homo sapiens integrin alpha FG-GAP repeat containing 3 (ITFG3), mRNA JAM3 83700 NM_032801 37 & 38 Homo sapiens junctional adhesion molecule 3 (JAM3), mRNA KLHL17 339451 NM_198317 39 & 40 Homo sapiens kelch-like 17 (Drosophila) (KLHL17), mRNA KRT24 192666 NM_019016 41 & 42 Homo sapiens keratin 24 (KRT24), mRNA MAD2L1BP 9587 NM_014628 43 & 44 Homo sapiens MAD2L1 binding protein (MAD2L1BP), transcript variant 2, mRNA MANSC1 54682 NM_018050 45 & 46 Homo sapiens MANSC domain containing 1 (MANSC1), mRNA MOBKL1B 55233 NM_018221 47 & 48 Homo sapiens MOB1, Mps One Binder kinase activator-like 1B (yeast) (MOBKL1B), mRNA NCBP1 4686 NM_002486 49 & 50 Homo sapiens nuclear cap binding protein subunit 1, 80 kDa (NCBP1), mRNA NMU 10874 NM_006681 51 & 52 Homo sapiens neuromedin U (NMU), mRNA PAPLN 89932 NM_173462 53 & 54 Homo sapiens papilin, proteoglycan-like sulfated glycoprotein (PAPLN), mRNA PCDH1 5097 NM_002587 55 & 56 Homo sapiens protocadherin 1 (PCDH1), transcript variant 1, mRNA PDGFB 5155 NM_002608 57 & 58 Homo sapiens platelet-derived growth factor beta polypeptide (simian sarcoma viral (v-sis) oncogene homolog) (PDGFB), transcript variant 1, mRNA PHOSPHO2 493911 NM_001008489 59 & 60 Homo sapiens phosphatase, orphan 2 (PHOSPHO2), mRNA PSENEN 55851 NM_172341 61 & 62 Homo sapiens presenilin enhancer 2 homolog (C. elegans) (PSENEN), mRNA SATB1 6304 NM_002971 63 & 64 Homo sapiens SATB homeobox 1 (SATB1), transcript variant 1, mRNA SNX11 29916 NM_013323 65 & 66 Homo sapiens sorting nexin 11 (SNX11), transcript variant 2, mRNA SPTA1 6708 NM_003126 67 & 68 Homo sapiens spectrin, alpha, erythrocytic 1 (elliptocytosis 2) (SPTA1), mRNA TMEM79 84283 NM_032323 69 & 70 Homo sapiens transmembrane protein 79 (TMEM79), transcript variant 1, mRNA TMIGD2 126259 NM_144615 71 & 72 Homo sapiens transmembrane and immunoglobulin domain containing 2 (TMIGD2), mRNA TUBB6 84617 NM_032525 73 & 74 Homo sapiens tubulin, beta 6 (TUBB6), mRNA TYROBP 7305 NM_198125 75 & 76 Homo sapiens TYRO protein tyrosine kinase binding protein (TYROBP), transcript variant 2, mRNA YTHDF1 54915 NM_017798 77 & 78 Homo sapiens YTH domain family, member 1 (YTHDF1), mRNA ZIC5 85416 NM_033132 79 & 80 Homo sapiens Zic family member 5 (odd- paired homolog, Drosophila) (ZIC5), mRNA

Each of the accession numbers identified in Table 1, and their corresponding sequences, are hereby incorporated herein by reference.

In various embodiments, the level of expression of at least 2, 3, 4, 5, 6, 7, 8, 9 or 10 biomarkers selected from the group of biomarkers listed in Table 1 is determined.

In particular embodiments, a predictive gene signature comprising a sub-combination of 2 or more biomarkers selected from the group of biomarkers listed in Table 1 is used. In various embodiments, the level of expression of at least 2, at least 3, at least 4 or at least 5 biomarkers selected from the group of biomarkers listed in Table 1 is determined. For example, the predictive gene signature may include at least 2 biomarkers, e.g., DYSF and EDIL3; GNAT1 and ERGIC3; KRT24 and PAPLN; MANSC1 and PDGFB; PCDH1 and PDGFB; or PHOSPHO2 and PSENEN. In another embodiment, the predictive gene signature may include at least 3 biomarkers, e.g., COL7A1, YTHDF1 and ZIC5; CKLF, IL10 and TUBB6; CDC20, CFL1 and TMEM79; HYAL2, NCBP1 and SNX11; or CEP152, NCBP1 and SATB1. In another embodiment, the predictive gene signature may include at least 4 biomarkers, e.g., APBB2, CCL26, PSENEN and SATB1; ANG, JAM3, KLHL17 and PAPLN; ITFG3, MAD2L1BP, NMU and PDGFB; SPTA1, TYROBP, SNX11 and PSENEN; GRAMD4, GNAT1, TMIGD2 and YTHDF1; or GRAMD4, HYAL2, PHOSPHO2 and TUBB6. In another embodiment, the predictive gene signature may include at least 5 biomarkers, e.g., CCL26, CDC20, ERGIC3, EDIL3 and PCDH1; DYSF, NMU, PHOSPHO2, PSENEN and SNX11; APBB2, CKLF, CYP4F3, TUBB6 and YTHDF1; or CEP152, MAD2L1BP, SPTA1, TMEM79 and ZIC5.

In particular embodiments, the predictive gene signature may include 2 or more of biomarkers ABI3, ANG, APBB2, CCL26, CDC20, CEP152, CFL1, CKLF, COL7A1, CYP4F3, DYSF, GNAT1, GRAMD4, HYAL2, IL10, ITFG3, JAM3, KLHL17, KRT24, MAD2L1BP, MANSC1, MOBKL1B, NCBP1, NMU, PCDH1, PHOSPHO2, SPTA1, TMIGD2, TYROBP, ZIC5, ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1, e.g., ABI3 and ANG; APBB2 and CCL26; GNAT1 and GRAMD4; IL10 and ITFG3; MACSC1 and MOBKL1B; NMU and PCDH1; or TYROBP and ZIC5. In other embodiments, the predictive gene signature includes at least 3 of the previously recited biomarkers, e.g., ABI3, ANG and APBB2; CCL26, CKLF and COL7A1; DYSF, GNAT1 and HYAL2; JAM3, KLHL17 and KRT24; NCBP1, NMU and PCDH1; SPTA1, TMIGD2 and TYROBP; or ZIC5, MAD2L1BP and CDC20. In other embodiments, the predictive gene signature includes at least 4 of the previously recited biomarkers, e.g., ABI3, ANG, APBB2 and CCL26; CEP152, CFL1, CKLF and COL7A1; KRT24, MANSC1, MOBKL1B and SPTA1; TYROBP, TMIGD2, PHOSPHO2 and NMU; ABI3, GNATI, KLHL17 and SPTA1; or CEP152, HYAL2, PCDH1 and TMIGD2. In yet further embodiments, the predictive gene signature includes at least 5 of the previously recited biomarkers, e.g., CKLF, COL7A1, GRAMD4, JAM3 and PCDH1; APBB2, CEP152, DYSF, IL10 and TYROBP; CYP4F3, HYAL2, ITFG3, KLHL17 and KRT24; NCBP1, SPTA1, TMIGD2, IL10 and JAM3; or CCL26, PHOSPHO2, SPTA1, TMIGD2 and ZIC5.

In other embodiments, the predictive gene signature may include 2 or more of biomarkers ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79 or YTHDF1, or any sub-combination thereof, e.g., ERGIC3 and PDGFB; ERGIC3 and PSENEN; ERGIC3 and SATB1; ERGIC3 and SNX11; ERGIC3 and TMEM79; ERGIC3 and YTHDF1; PDGFB and PSENEN; PDGFB and SATB1; PDGFB and SNX11; PDGFB and TMEM79; PDGFB and YTHDF1; PSENEN and SATB1; PSENEN and SNX11; PSENEN and TMEM79; PSENEN and YTHDF1; SATB1 and SNX11; SATB1 and TMEM79; SATB1 and YTHDF1; SNX11 and TMEM79; SNX11 and YTHDF1; or TMEM79 and YTHDF1. In other embodiments, the predictive gene signature includes at least 3 biomarkers, for example, ERGIC3, PDGFB and PSENEN; SATB1, SNX11 and TMEM79; SNX11, TMEM79 and YTHDF1; or ERGIC3, PDGFB and SATB1. In further embodiments, the predictive gene signature includes at least 4 biomarkers, for example, ERGIC3, PDGFB, PSENEN and SATB1; SNX11, TMEM79, YTHDF1 and ERGIC3; or ERGIC3, PDGFB, PSENEN and YTHDF1. In further embodiments, the predictive gene signature includes at least 5 biomarkers, for example, ERGIC3, PDGFB, PSENEN, SATB1 and SNX11; ERGIC3, PDGFB, PSENEN, SATB1 and TMEM79; or PSENEN, SATB1, SNX11, TMEM79 and YTHDF1. In yet further embodiments, the predictive gene signature includes at least 6 biomarkers, for example, ERGIC3, PDGFB, PSENEN, SATB1, SNX11 and TMEM79; PDGFB, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1; or ERGIC3, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1. In yet another embodiment, the predictive gene signature includes 7 biomarkers, for example, ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79 and YTHDF1.

In various embodiments, the biomarker is not one or more of SPTA1, PAPLN, PCDH1, TMIGD2 and/or KRT24. In a particular embodiment, the biomarker is not SPTA1, PAPLN, PCDH1, TMIGD2 and KRT24. In one embodiment, the biomarker is not SPTA1. In another embodiment, the biomarker is not PAPLN. In another embodiment, the biomarker is not PCDH1. In an alternative embodiment, the biomarker is not TMIGD2. In yet another embodiment, the biomarker is not KRT24.

In particular embodiments, the predictive gene signature may include 2 or more of biomarkers ABI3, ANG, APBB2, CCL26, CDC20, CEP152, CFL1, CKLF, COL7A1, CYP4F3, DYSF, GNAT1, GRAMD4, HYAL2, IL10, ITFG3, JAM3, KLHL17, MAD2L1BP, MANSC1, MOBKL1B, NCBP1, NMU, PHOSPHO2, TYROBP, ZIC5, ERGIC3, PDGFB, PSENEN, SATB1, SNX11, TMEM79, YTHDF1, EDIL3 and TUBB6, e.g., ABI3 and ANG; GRAMD4 and HYAL2; NMU and PHOSPHO2; ZIC5 and PSENEN; or SNX11 and MOBKL1B. In other embodiments, the predictive gene signature includes at least 3 of the previously recited biomarkers, e.g., APBB2, CDC20 and CKLF; COL7A1, DYSF and GNAT1; NCBP1, SATB1 and EDIL3; PSENEN, DYSF and GNAT1; MANSC1, ZIC5 and CFL1; or CKLF, GRAMD4 and NMU. In other embodiments, the predictive gene signature includes at least 4 of the previously recited biomarkers, e.g., ANG, CCL26, CEP152 and JAM3; APBB2, CYP4F3, ITFG3 and TYROBP; CYP4F3, MANSC1, PDGFB and YTHDF1; TUBB6, DYSF, PHOSPHO2 and CDC20; or CKLF, KLHL17, HYAL2 and ZIC5. In yet further embodiments, the predictive gene signature includes at least 5 of the previously recited biomarkers, e.g., IL10, CEP152, COL7A1, TYROBP and ERGIC3; TMEM79, SNX11, PSENEN, GNAT1 and GRAMD4; JAM3, SNX11, KLHL17, MOBKL1B and ERGIC3; or NMU, PHOSPHO2, PDGFB, CFL1 and ANG.

In various methods and or kits of the invention, the biomarker is not ABI3, is not ANG, is not APBB2, is not CCL26, is not CDC20, is not CEP152, is not CFL1, is not CKLF, is not COL7A1, is not CYP4F3, is not DYSF, is not GNAT1, is not GRAMD4, is not HYAL2, is not IL10, is not ITFG3, is not JAM3, is not KLHL17, is not KRT24, is not MAD2L1BP, is not MANSC1, is not MOBKL1B, is not NCBP1, is not NMU, is not PCDH1, is not PHOSPHO2, is not SPTA1, is not TMIGD2, is not TYROBP, is not ZIC5, is not ERGIC3, is not PDGFB, is not PSENEN, is not SATB1, is not SNX11, is not TMEM79, is not EDIL3, is not PAPLN, is not TUBB6 and/or is not YTHDF1.

Any suitable analytical method, can be utilized in the methods of the invention to assess (directly or indirectly) the level of expression of a biomarker in a sample. In some embodiments, a difference is observed between the level of expression of a biomarker, as compared to the control level of expression of the biomarker. In one embodiment, the difference is greater than the limit of detection of the method for determining the expression level of the biomarker. In further embodiments, the difference is greater than or equal to the standard error of the assessment method, and preferably the difference is at least about 2-, about 3-, about 4-, about 5-, about 6-, about 7-, about 8-, about 9-, about 10-, about 15-, about 20-, about 25-, about 100-, about 500- or about 1000-fold greater than the standard error of the assessment method. In some embodiments, the level of expression of the biomarker in a sample as compared to a control level of expression is assessed using parametric or nonparametric descriptive statistics, comparisons, regression analyses, and the like.

In some embodiments, a difference in the level of expression of the biomarker in the sample derived from the subject is detected relative to the control, and the difference is about 5%, about 10%, about 15%, about 20%, about 25%, about 30%, about 40%, about 50%, about 60%, about 70%, about 80%, or about 90% less than the expression level of the biomarker in the control sample.

The level of expression of a biomarker, for example, as set forth in Table 1, in a sample obtained from a subject may be assayed by any of a wide variety of techniques and methods, which transform the biomarker within the sample into a moiety that can be detected and/or quantified. Non-limiting examples of such methods include analyzing the sample using immunological methods for detection of proteins, protein purification methods, protein function or activity assays, nucleic acid hybridization methods, nucleic acid reverse transcription methods, and nucleic acid amplification methods, immunoblotting, Western blotting, Northern blotting, electron microscopy, mass spectrometry, e.g., MALDI-TOF and SELDI-TOF, immunoprecipitations, immunofluorescence, immunohistochemistry, enzyme linked immunosorbent assays (ELISAs), e.g., amplified ELISA, quantitative blood based assays, e.g., serum ELISA, quantitative urine based assays, flow cytometry, Southern hybridizations, array analysis, and the like, and combinations or sub-combinations thereof.

In one embodiment, the level of expression of the biomarker in a sample is determined by detecting a transcribed polynucleotide, or portion thereof, e.g., mRNA, or cDNA, of the biomarker gene. RNA may be extracted from cells using RNA extraction techniques including, for example, using acid phenol/guanidine isothiocyanate extraction (RNAzol B; Biogenesis), RNeasy RNA preparation kits (Qiagen) or PAXgene (PreAnalytix, Switzerland). Typical assay formats utilizing ribonucleic acid hybridization include nuclear run-on assays, RT-PCR, quantitative PCR analysis, RNase protection assays (Melton et al., Nuc. Acids Res. 12:7035), Northern blotting and in situ hybridization. Other suitable systems for mRNA sample analysis include microarray analysis (e.g., using Affymetrix's microarray system or Illumina's BeadArray Technology).

In one embodiment, the level of expression of the biomarker is determined using a nucleic acid probe. The term “probe”, as used herein, refers to any molecule that is capable of selectively binding to a specific biomarker. Probes can be synthesized by one of skill in the art, or derived from appropriate biological preparations. Probes can be specifically designed to be labeled, by addition or incorporation of a label. Examples of molecules that can be utilized as probes include, but are not limited to, RNA, DNA, proteins, antibodies, and organic molecules.

As indicated above, isolated mRNA can be used in hybridization or amplification assays that include, but are not limited to, Southern or Northern analyses, polymerase chain reaction (PCR) analyses and probe arrays. One method for the determination of mRNA levels involves contacting the isolated mRNA with a nucleic acid molecule (probe) that can hybridize to the biomarker mRNA. The nucleic acid probe can be, for example, a full-length cDNA, or a portion thereof, such as an oligonucleotide of at least about 7, 10, 15, 20, 25, 30, 35, 40, 45, 50, 100, 250 or about 500 nucleotides in length and sufficient to specifically hybridize under appropriate hybridization conditions to the biomarker genomic DNA. In a particular embodiment the probe will bind the biomarker genomic DNA under stringent conditions. Such stringent conditions, for example, hybridization in 6× sodium chloride/sodium citrate (SSC) at about 45° C., followed by one or more washes in 0.2×SSC, 0.1% SDS at 50-65° C., are known to those skilled in the art and can be found in Current Protocols in Molecular Biology, Ausubel et al., eds., John Wiley & Sons, Inc. (1995), sections 2, 4, and 6, the teachings of which are hereby incorporated by reference herein. Additional stringent conditions can be found in Molecular Cloning: A Laboratory Manual, Sambrook et al., Cold Spring Harbor Press, Cold Spring Harbor, N.Y. (1989), chapters 7, 9, and 11, the teachings of which are hereby incorporated by reference herein.

In one embodiment, the mRNA is immobilized on a solid surface and contacted with a probe, for example by running the isolated mRNA on an agarose gel and transferring the mRNA from the gel to a membrane, such as nitrocellulose. In an alternative embodiment, the probe(s) are immobilized on a solid surface, for example, in an Affymetrix gene chip array, and the probe(s) are contacted with mRNA. A skilled artisan can readily adapt mRNA detection methods for use in determining the level of the biomarker mRNA.

The level of expression of the biomarker in a sample can also be determined using methods that involve the use of nucleic acid amplification and/or reverse transcriptase (to prepare cDNA) of for example mRNA in the sample, e.g., by RT-PCR (the experimental embodiment set forth in Mullis, 1987, U.S. Pat. No. 4,683,202), ligase chain reaction (Barany (1991) Proc. Natl. Acad. Sci. USA 88:189-193), self sustained sequence replication (Guatelli et al. (1990) Proc. Natl. Acad. Sci. USA 87:1874-1878), transcriptional amplification system (Kwoh et al. (1989) Proc. Natl. Acad. Sci. USA 86:1173-1177), Q-Beta Replicase (Lizardi et al. (1988) Bio/Technology 6:1197), rolling circle replication (Lizardi et al., U.S. Pat. No. 5,854,033) or any other nucleic acid amplification method, followed by the detection of the amplified molecules. These approaches are especially useful for the detection of nucleic acid molecules if such molecules are present in very low numbers. In particular aspects of the invention, the level of expression of the biomarker is determined by quantitative fluorogenic RT-PCR (e.g., the TaqMan™ System). Such methods typically utilize pairs of oligonucleotide primers that are specific for the biomarker. Methods for designing oligonucleotide primers specific for a known sequence are well known in the art.

The expression levels of biomarker mRNA can be monitored using a membrane blot (such as used in hybridization analysis such as Northern, Southern, dot, and the like), or microwells, sample tubes, gels, beads or fibers (or any solid support comprising bound nucleic acids). See, for example, U.S. Pat. Nos. 5,770,722, 5,874,219, 5,744,305, 5,677,195 and 5,445,934, the contents of which as they relate to these assays are incorporated herein by reference. The determination of biomarker expression level may also comprise using nucleic acid probes in solution.

In one embodiment of the invention, microarrays are used to detect the level of expression of a biomarker. Microarrays are particularly well suited for this purpose because of the reproducibility between different experiments. DNA microarrays provide one method for the simultaneous measurement of the expression levels of large numbers of genes. Each array consists of a reproducible pattern of capture probes attached to a solid support. Labeled RNA or DNA is hybridized to complementary probes on the array and then detected by laser scanning. Hybridization intensities for each probe on the array are determined and converted to a quantitative value representing relative gene expression levels. See, e.g., U.S. Pat. Nos. 6,040,138, 5,800,992 and 6,020,135, 6,033,860, and 6,344,316, the contents of which as they relate to these assays are incorporated herein by reference. High-density oligonucleotide arrays are particularly useful for determining the gene expression profile for a large number of RNA's in a sample.

Expression of a biomarker can also be assessed at the protein level, using a detection reagent that detects the protein product encoded by the mRNA of the biomarker, directly or indirectly. For example, if an antibody reagent is available that binds specifically to a biomarker protein product to be detected, then such an antibody reagent can be used to detect the expression of the biomarker in a sample from the subject, using techniques, such as immunohistochemistry, ELISA, FACS analysis, and the like.

Other known methods for detecting the biomarker at the protein level include methods such as electrophoresis, capillary electrophoresis, high performance liquid chromatography (HPLC), thin layer chromatography (TLC), hyperdiffusion chromatography, and the like, or various immunological methods such as fluid or gel precipitation reactions, immunodiffusion (single or double), immunoelectrophoresis, radioimmunoassay (RIA), enzyme-linked immunosorbent assays (ELISAs), immunofluorescent assays, and Western blotting.

Proteins from samples can be isolated using a variety of techniques, including those well known to those of skill in the art. The protein isolation methods employed can, for example, be those described in Harlow and Lane (Harlow and Lane, 1988, Antibodies: A Laboratory Manual, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.).

In one embodiment, antibodies, or antibody fragments, are used in methods such as Western blots or immunofluorescence techniques to detect the expressed proteins. Antibodies for determining the expression of the biomarkers of the invention are commercially available. For example, ERGIC-3 specific antibodies are commercially available from Santa Cruz Biotechnology, Inc. (ERGIC-3 (P-16) Antibody and ERGIC-3 (Y-23) Antibody) and Sigma Aldrich (HPA015968, AV47209, HPA015242, SAB4502151). PDGFB specific antibodies are commercially available from Santa Cruz Biotechnology, Inc. (e.g., PDGF-B (C-5) Antibody and PDGF-B (H-55) Antibody) and Sigma Aldrich (e.g., HPA011972, SAB2101755 and SAB2900226). PSENEN specific antibodies are commercially available from Origene (e.g., Catalog No. TA306367) and Sigma Aldrich (e.g., PRS3981, WH0055851M1, PRS3979 and P5622). Further by way of example, SATB1 antibodies are commercially available from, for example, Abcam (Catalog No. ab49061, ab92307 and ab70004), Abnova Corporation (Catalog No. PAB13379), and Aviva Systems Biology (Catalog No. ARP33362_P050). SNX11 antibodies are commercially available from Abcam (Catalog Nos. ab4128, ab67578, ab76816 and ab76762) and Abnova Corporation (Catalog Nos. PAB6362 and H00029916-B01). TMEM79 Antibodies are commercially available from, for example, Abcam (Catalog No. ab81539) and Sigma Aldrich (Catalog No. SAB2102475). Finally, YTHDF1 antibodies are commercially available from, for example, Abnova Corporation (Catalog No. PAB17446), Aviva Systems Biology (Catalog No. ARP57032_P050) and Santa Cruz Biotechnology (Catalog No. sc-86026).

It is generally preferable to immobilize either the antibody or proteins on a solid support for Western blots and immunofluorescence techniques. Suitable solid phase supports or carriers include any support capable of binding an antigen or an antibody. Well-known supports or carriers include glass, polystyrene, polypropylene, polyethylene, dextran, nylon, amylases, natural and modified celluloses, polyacrylamides, gabbros, and magnetite.

One skilled in the art will know many other suitable carriers for binding antibody or antigen, and will be able to adapt such support for use with the present invention. For example, protein isolated from cells can be run on a polyacrylamide gel electrophoresis and immobilized onto a solid phase support such as nitrocellulose. The support can then be washed with suitable buffers followed by treatment with the detectably labeled antibody. The solid phase support can then be washed with the buffer a second time to remove unbound antibody. The amount of bound label on the solid support can then be detected by conventional means. Means of detecting proteins using electrophoretic techniques are well known to those of skill in the art (see generally, R. Scopes (1982) Protein Purification, Springer-Verlag, N.Y.; Deutscher, (1990) Methods in Enzymology Vol. 182: Guide to Protein Purification, Academic Press, Inc., N.Y.).

Other standard methods include immunoassay techniques which are well known to one of ordinary skill in the art and may be found in Principles And Practice Of Immunoassay, 2nd Edition, Price and Newman, eds., MacMillan (1997) and Antibodies, A Laboratory Manual, Harlow and Lane, eds., Cold Spring Harbor Laboratory, Ch. 9 (1988), each of which is incorporated herein by reference in its entirety.

Antibodies used in immunoassays to determine the level of expression of the biomarker, may be labeled with a detectable label. The term “labeled”, with regard to the probe or antibody, is intended to encompass direct labeling of the probe or antibody by incorporation of a label (e.g., a radioactive atom), coupling (i.e., physically linking) a detectable substance to the probe or antibody, as well as indirect labeling of the probe or antibody by reactivity with another reagent that is directly labeled. Examples of indirect labeling include detection of a primary antibody using a fluorescently labeled secondary antibody and end-labeling of a DNA probe with biotin such that it can be detected with fluorescently labeled streptavidin.

In one embodiment, the antibody is labeled, e.g. a radio-labeled, chromophore-labeled, fluorophore-labeled, or enzyme-labeled antibody. In another embodiment, an antibody derivative (e.g., an antibody conjugated with a substrate or with the protein or ligand of a protein-ligand pair (e.g., biotin-streptavidin), or an antibody fragment (e.g. a single-chain antibody, or an isolated antibody hypervariable domain) which binds specifically with the biomarker is used.

In one embodiment of the invention, proteomic methods, e.g., mass spectrometry, are used. Mass spectrometry is an analytical technique that consists of ionizing chemical compounds to generate charged molecules (or fragments thereof) and measuring their mass-to-charge ratios. In a typical mass spectrometry procedure, a sample is obtained from a subject, loaded onto the mass spectrometry, and its components (e.g., the biomarker) are ionized by different methods (e.g., by impacting them with an electron beam), resulting in the formation of charged particles (ions). The mass-to-charge ratio of the particles is then calculated from the motion of the ions as they transit through electromagnetic fields.

For example, matrix-associated laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) or surface-enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF MS) which involves the application of a biological sample, such as serum, to a protein-binding chip (Wright, G. L., Jr., et al. (2002) Expert Rev Mol Diagn 2:549; Li, J., et al. (2002) Clin Chem 48:1296; Laronga, C., et al. (2003) Dis biomarkers 19:229; Petricoin, E. F., et al. (2002) 359:572; Adam, B. L., et al. (2002) Cancer Res 62:3609; Tolson, J., et al. (2004) Lab Invest 84:845; Xiao, Z., et al. (2001) Cancer Res 61:6029) can be used to determine the expression level of a biomarker at the protein level.

Furthermore, in vivo techniques for determination of the expression level of the biomarker include introducing into a subject a labeled antibody directed against the biomarker, which binds to and transforms the biomarker into a detectable molecule. As discussed above, the presence, level, or even location of the detectable biomarker in a subject may be detected by standard imaging techniques.

In general, where a difference in the level of expression of a biomarker and the control is to be detected, it is preferable that the difference between the level of expression of the biomarker in a sample from a subject having breast cancer and being treated with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), or being considered for treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), and the amount of the biomarker in a control sample, is as great as possible. Although this difference can be as small as the limit of detection of the method for determining the level of expression, it is preferred that the difference be greater than the limit of detection of the method or greater than the standard error of the assessment method, and preferably a difference of at least about 2-, about 3-, about 4-, about 5-, about 6-, about 7-, about 8-, about 9-, about 10-, about 15-, about 20-, about 25-, about 100-, about 500-, 1000-fold greater than the standard error of the assessment method.

In another aspect, the present invention provides methods for determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer by determining and/or identifying whether the subject carries at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a polymorphism, for example, a mutation, that results in decreased expression and/or reduced function of the encoded protein, wherein the presence of a polymorphism in at least one gene is indicative that eribulin, an analog thereof, or a pharmaceutically acceptable salt there, will be effective in treating a subject. In another aspect, the present invention provides methods for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), will be effective in treating a subject having breast cancer by assaying a sample derived from the subject to determine whether the subject carries at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a polymorphism, for example, a mutation, that results in decreased expression and/or reduced function of the encoded protein, wherein the presence of the polymorphism in at least one gene in said sample is indicative that eribulin, an analog thereof, or a pharmaceutically acceptable salt there, may be used to treat said subject. In a further aspect, a method is provided for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, will be effective in treating a subject having breast cancer, the method comprising determining the presence of a polymorphism that results in reduced expression and/or function in a gene encoding a biomarker selected from the group of biomarkers listed in Table 1 in a sample derived from said subject, and predicting that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, may be used to treat said subject based on the presence of the polymorphism.

In a further aspect, the present invention provides methods for determining the sensitivity of a breast tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof by determining and/or identifying whether said tumor contains a polymorphism in at least one gene resulting in reduced expression and/or function of the encoded protein, wherein the gene is selected from the group of biomarkers set forth in Table 1. Identification and/or determination that the tumor contains such a polymorphism is indicative of sensitivity of said tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof. In yet another aspect, the present invention is directed to methods for treating a subject having breast cancer with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof by identifying whether a sample derived from said subject has at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a polymorphism resulting in reduced expression and/or function of the encoded protein and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) to the subject when the polymorphism is identified.

In another aspect, the present invention provides methods for determining whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer by determining and/or identifying whether the subject carries at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a null mutation, wherein the presence of a null mutation in at least one gene is indicative that eribulin, an analog thereof, or a pharmaceutically acceptable salt there, will be effective in treating the subject. In another aspect, the present invention provides methods for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer by assaying a sample derived from the subject to determine whether the subject carries at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a null mutation, wherein the presence of a null mutation in at least one gene in said sample is indicative that eribulin, an analog thereof, or a pharmaceutically acceptable salt there, will be effective in treating the subject. In a further aspect, a method is provided for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, may be used to treat a subject having breast cancer, the method comprising determining the presence of a null mutation in a biomarker selected from the group of biomarkers listed in Table 1 in a sample derived from said subject, and predicting that eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, may be used to treat said subject based on the presence of said null mutation.

In a further aspect, the present invention provides methods for determining the sensitivity of a breast tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof by determining and/or identifying whether said tumor contains a null mutation in at least one gene, selected from the group of biomarkers set forth in Table 1. Identification and/or determination that the tumor contains a null mutation is indicative of sensitivity of said tumor to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof. In yet another aspect, the present invention is directed to methods for treating a subject having breast cancer with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof by identifying whether a sample derived from said subject has at least one gene, selected from the group of biomarkers set forth in Table 1, which contains a null mutation and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) to the subject when a null mutation is identified.

As used herein, the term “null mutation” refers to a mutation in a genomic DNA sequence that causes the product of the gene to be non-functional or largely absent. Such mutations may occur in the coding and/or regulatory regions of the gene, and may be changes of individual residues, or insertions or deletions of regions of nucleic acids. These mutations may also occur in the coding and/or regulatory regions of other genes which may regulate or control the gene and/or the product of the gene so as to cause the gene product to be non-functional or largely absent. The null mutation may be a deletion of the native gene or a portion thereof. These sequence disruptions or modifications may include insertions, missense, frameshift, deletion, or substitutions, or replacements of DNA sequence, or any combination thereof. For example, the null mutation may result in the insertion of a premature stop codon. The null mutation results in functional inactivation of the gene product by, for example, inhibiting its production partially or completely; disrupting, inhibiting or curtailing the translation of the protein product, or resulting in a nonfunctional protein. The null mutation may be a pre-existing mutation in the subject or a mutation which arose in a tumor. The presence of a null mutation in a biomarker can be indicated by a lack of detectable expression of the biomarker. However, the presence of a null mutation can be determined by other methods. For example, in such embodiments, a sample of the subject's DNA may be sequenced in order to identify the presence of a null mutation. Any of the well-known methods for sequencing the biomarkers may be used in the methods of the invention, such as the methods described in, for example, U.S. Pat. No. 5,075,216, Engelke et al. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 544-548 and Wong et al. (1987) Nature 330, 384-386; Maxim and Gilbert (1977) Proc. Natl. Acad. Sci. U.S.A. 74:560; or Sanger (1977) Proc. Natl. Acad. Sci. U.S.A. 74:5463. In addition, any of a variety of automated sequencing procedures can be utilized see, e.g., Naeve, C. W et al. (1995) Biotechniques 19:448, including sequencing by mass spectrometry (see, e.g., PCT International Publication No. WO 94/16101; Cohen et al. (1996) Adv. Chromatogr. 36:127-162; and Griffin et al. (1993) Appl. Biochem. Biotechnol. 38:147-159.

Determining the presence or absence of a null mutation in the sample may also be accomplished using various techniques such as polymerase chain reaction (PCR) amplification reaction, reverse-transcriptase PCR analysis, single-strand conformation polymorphism analysis (SSCP), mismatch cleavage detection, heteroduplex analysis, Southern blot analysis, Western blot analysis, deoxyribonucleic acid sequencing, restriction fragment length polymorphism analysis, haplotype analysis, serotyping, and combinations or sub-combinations thereof.

Any suitable sample obtained from a subject having breast cancer can be used to assess the level of expression, including a lack of expression, of the biomarker, for example, a biomarker provided in Table 1. For example, the sample may be any fluid or component thereof, such as a fraction or extract, e.g., blood, plasma, lymph, cystic fluid, urine, nipple aspirates, or fluids collected from a biopsy (e.g., lump biopsy), obtained from the subject. In a typical situation, the fluid may be blood, or a component thereof, obtained from the subject, including whole blood or components thereof, including, plasma, serum, and blood cells, such as red blood cells, white blood cells and platelets. The sample may also be any tissue or fragment or component thereof, e.g., breast tissue, connective tissue, lymph tissue or muscle tissue obtained from the subject.

Techniques or methods for obtaining samples from a subject are well known in the art and include, for example, obtaining samples by a mouth swab or a mouth wash; drawing blood; or obtaining a biopsy. Isolating components of fluid or tissue samples (e.g., cells or RNA or DNA) may be accomplished using a variety of techniques.

The sample from the cancer may be obtained by biopsy of the patient's cancer. In certain embodiments, more than one sample from the patient's tumor is obtained in order to acquire a representative sample of cells for further study. For example, a patient with breast cancer may have a needle biopsy to obtain a sample of cancer cells. Several biopsies of the tumor may be used to obtain a sample of cancer cells. In other embodiments, the sample may be obtained from surgical excision of the tumor. In this case, one or more samples may be taken from the excised tumor for analysis using the methods of the invention.

After the sample is obtained, it may be further processed. The cancer cells may be cultured, washed, or otherwise selected to remove normal tissue. The cells may be trypsinized to remove the cells from the tumor sample. The cells may be sorted by fluorescence activated cell sorting (FACS) or other cell sorting technique. The cells may be cultured to obtain a greater number of cells for study. In certain instances the cells may be immortalized. For some applications, the cells may be frozen or the cells may be embedded in paraffin.

II. Treatment with Eribulin, Analogs Thereof, or Pharmaceutically Acceptable Salts Thereof (e.g., Eribulin Mesylate)

Given the observation that the expression levels of certain biomarkers, for example, those set forth in Table 1, in a subject having breast cancer influences the responsiveness of the subject to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), a skilled artisan can select an appropriate treatment regimen for the subject based on the expression levels of the biomarkers in the subject. Accordingly, the present invention provides methods for treating a subject having breast cancer by (i) identifying a subject having breast cancer in which at least one biomarker selected from the group of biomarkers listed in Table 1 has a low level of expression and (ii) administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), to the subject. In another aspect, the present invention provides methods for treating a subject having breast cancer by (i) assaying a sample derived from the subject to determine the level of expression of at least one biomarker selected from the group of biomarkers listed in Table 1 and (ii) administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) to the subject when a low level of expression of the at least one biomarker is detected in the sample.

In various embodiments, the subject may have been previously treated with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate). In other embodiments, the subject may be under consideration for treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), for the first time. The level of expression of one or more, e.g., at least 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10, biomarkers identified in Table 1 is determined. If level of expression of at least one biomarker (e.g., 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10 biomarkers) is determined to be a low level of expression, treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), is likely to be efficacious. However, it is not necessary that all of the biomarkers assayed have a low level of expression as compared to the respective control. For example, while certain biomarkers may be present at normal or high levels of expression, treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be indicated when, for example, a low level of expression is present for at least 1, at least 2, at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9 or at least 10 biomarkers.

When a low level of expression of one or more of the biomarkers of the invention is found (e.g., due to the presence of a null mutation in the biomarker gene) in a sample derived from a subject having breast cancer, the subject may be treated with eribulin, having the following the structure, with a pharmaceutically acceptable salt of eribulin, or with an eribulin analog or pharmaceutically acceptable thereof.

In some embodiments, a pharmaceutically acceptable salt of eribulin is administered to the subject, such as eribulin mesylate.

The treatment regimen for eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), that is selected typically includes at least one of the following parameters and more typically includes many or all of the following parameters: the dosage, the formulation, the route of administration and/or the frequency of administration. Selection of the particular parameters of the treatment regimen can be based on known treatment parameters for eribulin previously established in the art such as those described in the Dosage and Administration protocols set forth in the FDA Approved Label for HALAVEN®, the entire contents of which are incorporated herein by reference. For example, eribulin mesylate can be administered intravenously on Days 1 and 8 of a 21 day cycle, for example at a dose of 1.4 mg/m², or if a dose reduction is indicated (e.g., for hepatic or renal impairment), at a dose of 0.7 mg/m² or 1.1 mg/m². Various modifications to dosage, formulation, route of administration and/or frequency of administration can be made based on various factors including, for example, the disease, age, sex, and weight of the patient, as well as the severity or stage of cancer (see, for example, U.S. Pat. No. 6,653,341 and U.S. Pat. No. 6,469,182, the entire contents of each of which are hereby incorporated herein by reference).

As used herein, the term “therapeutically effective amount” means an amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) as described herein, that is capable of treating breast cancer. The dose of a compound to be administered according to this invention will, of course, be determined in light of the particular circumstances surrounding the case including, for example, the compound administered, the route of administration, condition of the patient, and the pathological condition being treated, for example, the stage of breast cancer.

For administration to a subject, eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), typically is formulated into a pharmaceutical composition comprising eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, and a pharmaceutically acceptable carrier. Therapeutic compositions typically should be sterile and adequately stable under the conditions of manufacture and storage. Pharmaceutical compositions also can be administered in a combination therapy, i.e., combined with other agents, such as those agents set forth below (see, for example, U.S. Pat. No. 6,214,865 and U.S. Pat. No. 6,653,341, the entire contents of each of which are hereby incorporated herein by reference).

As used herein, “pharmaceutically acceptable carrier” includes any and all solvents, dispersion media, coatings, antibacterial and antifungal agents, isotonic and absorption delaying agents, and the like that are physiologically compatible. Preferably, the carrier is suitable for parenteral (e.g., intravenous, intramuscular, subcutaneous, intrathecal) administration (e.g., by injection or infusion). Depending on the route of administration, the active compound may be coated in a material to protect the compound from the action of acids and other natural conditions that may inactivate the compound.

The pharmaceutical compositions may include one or more pharmaceutically acceptable salts, as defined above.

There are numerous types of anti-cancer approaches that can be used in conjunction with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate) treatment, according to the invention. These include, for example, treatment with chemotherapeutic agents, biological agents (e.g., hormonal agents, cytokines (such as interleukins, interferons, granulocyte colony stimulating factor (G-CSF), macrophage colony stimulating factor (M-CSF), and granulocyte macrophage colony stimulating factor (GM-CSF)), chemokines, vaccine antigens, and antibodies), anti-angiogenic agents (e.g., angiostatin and endostatin), radiation, and surgery, as described in more detail in U.S. Pat. No. 6,653,341 B1 and U.S. Publ. No. 2006/0104984 A1, the teachings of which are incorporated herein by reference in their entirety.

The methods of the invention can employ these approaches to treat the same types of cancers as those for which they are known in the art to be used, as well as others, as can be determined by those of skill in this art. Also, these approaches can be carried out according to parameters (e.g., regimens and doses) that are similar to those that are known in the art for their use. However, as is understood in the art, it may be desirable to adjust some of these parameters, due to the additional use of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), with these approaches. For example, if a drug is normally administered as a sole therapeutic agent, when combined with eribulin, according to the invention, it may be desirable to decrease the dosage of the drug, as can be determined by those of skill in this art. Examples of the methods of the invention, as well as compositions that can be used in these methods, are provided below.

Chemotherapeutic drugs of several different types including, for example, antimetabolites, antibiotics, alkylating agents, plant alkaloids, hormonal agents, anticoagulants, antithrombotics, and other natural products, among others, can be used in conjunction with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, according to the invention. Specific, non-limiting examples of these classes of drugs, as well as cancers that can be treated by their use, are as follows.

Numerous approaches for administering anti-cancer drugs are known in the art, and can readily be adapted for use in the present invention. In the case that one or more drugs are to be administered in conjunction with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), for example, the drugs can be administered together, in a single composition, or separately, as part of a comprehensive treatment regimen. For systemic administration, the drugs can be administered by, for example, intravenous infusion (continuous or bolus). Appropriate scheduling and dosing of such administration can readily be determined by those of skill in this art based on, for example, preclinical studies in animals and clinical studies (e.g., phase I studies) in humans.

Many regimens used to administer chemotherapeutic drugs involve, for example, intravenous administration of a drug (or drugs) followed by repetition of this treatment after a period (e.g., 1-4 weeks) during which the patient recovers from any adverse side effects of the treatment. It may be desirable to use both drugs at each administration or, alternatively, to have some (or all) of the treatments include only one drug (or a subset of drugs).

Kits of the Invention

The invention also provides compositions and kits for predicting whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer. These kits include reagents for determining the level of expression of at least one, for example, 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10, biomarker(s) selected form the group of biomarkers listed in Table 1 and instructions for use of the kit to predict whether eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), may be used to treat a subject having breast cancer.

The kits of the invention may optionally comprise additional components useful for performing the methods of the invention. By way of example, the kits may comprise reagents for obtaining a biological sample from a subject, a control sample, and/or eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate).

In one embodiment, the reagents for determining the expression level of at least one biomarker in a biological sample from the subject comprises a nucleic acid preparation sufficient to detect expression of a nucleic acid, e.g., mRNA, encoding the biomarker. This nucleic acid preparation includes at least one, and may include more than one, nucleic acid probe or primer, the sequence(s) of which is designed such that the nucleic acid preparation can detect the expression of nucleic acid, e.g., mRNA, encoding the biomarker in the sample from the subject. A preferred nucleic acid preparation includes two or more PCR primers that allow for PCR amplification of a segment of the mRNA encoding the biomarker of interest. In other embodiments, the kit includes a nucleic acid preparation for each of at least 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10 biomarkers provided in Table 1.

Alternatively, the reagents for detecting expression levels in the subject of one or more biomarkers predictive of responsiveness to eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), can comprise a reagent that detects the gene product of the nucleic acid encoding the biomarker(s) of interest sufficient to distinguish it from other gene products in a sample from the subject. A non-limiting example of such a reagent is a monoclonal antibody preparation (comprising one or more monoclonal antibodies) sufficient to detect protein expression of at least one biomarker in a sample from the subject, such as a peripheral blood mononuclear cell sample.

The means for determining the expression level of the biomarkers of Table 1 can also include, for example, buffers or other reagents for use in an assay for evaluating expression (e.g., at either the nucleic acid or protein level).

In another embodiment, the kit can further comprise eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof (e.g., eribulin mesylate), for treating breast cancer or another cancer, as described herein in the subject.

Preferably, the kit is designed for use with a human subject.

The present invention is further illustrated by the following examples which should not be construed as further limiting. The contents of all references, patents and published patent applications cited throughout this application, as well as the Figures and the Appendix of sequences provided herein, are expressly incorporated herein by reference in their entirety.

EXAMPLES Example 1 Identification of Resistance Biomarkers for Treatment with Eribulin

siRNA techniques were employed to “knock down” expression of certain genes and assess the sensitivity of the resulting knock down cells to eribulin. Based on these studies, the expression of those genes set forth in Table 1 were identified as being associated with the sensitivity of breast cancer cells to treatment with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof.

siRNA Transfection Optimization and Assay Development

Transfection conditions for human breast cancer cell lines MDA-MB-231 (ATCC Catalog No. HTB26™) and BT-549 (ATCC Catalog No. HTB122™) were optimized using transfection reagent DharmaFect 1 from Dharmacon. The MDA-MB-231 and BT-549 cell lines have been reported to be Estrogen Receptor (ER) negative, Progesterone Receptor (PR) negative and HER-2 negative (triple negative). As a non-targeting negative control we used Silencer Negative Control #1 siRNA from Applied Biosystems. The siGENOME TOX (siTOX) Transfection Control (Dharmacon), an RNA duplex designed to induce cell death, was used as a positive control for cell proliferation assays. A reverse transfection procedure in which siRNA was first mixed with transfection reagent and then cells were added to the well, was used in all experiments. Cell viability was compared in cells treated with medium, negative control siRNA and siTOX reagent combined with different amount of DharmaFect 1. Final selected transfection conditions were as follows: MDA-MB-231 cells at 0.035 μl of DharmaFect 1 per well, while BT-549 cells at 0.05 μl of DharmaFect 1 per well. Assays and library screening were performed at 50 nM final concentration of siRNAs. Efficacy of transfection was further confirmed by qPCR with control SMARTpool siRNA reagents targeting PPIA and GAPDH genes (Dharmacon).

High-Throughput siRNA Screening

The whole human genome siRNA library was purchased from Dharmacon. The library was diluted to 5 μM. Each well contained 4 SMARTpool siRNA reagents, each directed against a particular gene (four siRNAs targeting the same gene in a single well). More then 18,500 human genes were targeted with this library. 4 μl of each set of siRNAs from the library plates were transferred to 384-well master plates containing 36 μl OPTI-MEM medium per well. 40 μl of diluted DharmaFect 1 reagent were added to each well of the master plate and mixed. 10 μl of siRNA and transfection reagent mixture per well were distributed into five screening plates. After 10 min incubation, cells in 40 μl of growth medium were added to each well. Each screening plate included several replicates of negative control siRNA, positive control siTOX as well as medium plus transfection reagent (no siRNA) containing wells. After a 24 hour incubation, 3 screening plates received 10 μl of DMSO diluted in cell growth medium, while 2 repeats were treated with 10 μl of eribulin mesylate (E7389) in growth medium, yielding a final concentration corresponding to the IC₂₀ for E7389 for the cell line tested (0.75 nM E7389 for MDA-MB-231; eribulin was provided in a stock solution of DMSO and diluted in growth medium) (see FIG. 1). Cell viability was determined at 96 hours after transfection by CellTiter-Glo luminescent assay from Promega. 10 μl of CellTiter-Glo solution per well were used. Plates were mixed for 2 minutes on a horizontal shaker, incubated for 10 minutes and read on an EnVision® multilabel plate reader from PerkinElmer.

Identification of Primary Hits

Identification of genes with a significant effect on cell sensitivity to E7389 was performed by a method that was similar to the method described for a paclitaxel siRNA screen (Whitehurst et al. (2007) Nature 446:815-819). Briefly, measurement of each well was normalized by average of medium plus transfection reagent containing reference wells on a plate (32 wells/plate). The biological replicates were averaged for DMSO and E7389-treated plates. For each gene, a two sample t-test was performed to identify significantly different values for wells treated with two different conditions. To narrow down the hit list, the magnitude of response was taken into account by arranging all data according to fold change ratio (average E7389/average DMSO) in ascending order. 364 genes with a fold change among the lowest 5 percentile of the distribution passed the cut-off level. Then, hypothetical open reading frames and genes encoding hypothetical proteins were excluded and the analysis was focused on the 240 remaining genes (see FIG. 2).

Confirmation Assays

siRNA SMARTpools for the 240 selected genes were ordered in ON-TARGETplus format from Dharmacon. These reagents contain a modified sense strand to prevent interaction with RISC and favor antisense strand uptake. The antisense strand seed region is modified to decrease off-target activity and enhance target specificity. These reagents were used for confirmation secondary screening. To identify common genes influencing sensitivity of cancer cells to E7389, BT-549 breast cancer cells were screened with the 240 selected siRNA pools. The screening was performed using the same protocol as the primary screen with MDA-MB-231 cells, with the final concentration of eribulin mesylate (E7389) in each well corresponding to the IC₂₀ for BT-549 cells (0.25 nM E7389).

Data analysis showed that the treatment with 40 out of 240 siRNA pools caused significant differences when comparing E7389-treated wells to carrier-treated wells in both cell lines (Table 2).

To confirm specific down-regulation of 40 genes with siRNA pools, quantitative PCR analysis of targeted mRNAs was performed. MDA-MB-231 and BT-549 cells were transfected with 40 ON-TARGETplus siRNAs or non-targeting negative control siRNA according to the above protocol. 48 hours later cells were lysed and cDNAs were synthesized according to the manufacturer's instructions for use of the TaqMan® Gene Expression Cells-to-CT™ Kit (Applied Biosystems). Relative quantities of remaining cDNAs after the treatment with siRNAs were evaluated using QuantiTect SYBR Green PCR Kit with the gene-specific QuantiTect Primer Assays (Qiagen). Results of the analysis are shown in FIG. 4. The following 18 genes were down-regulated more than 50 percent in both tested cell lines: CFL1, NMU, MOBKL1B, HYAL2, PSENEN, CYP4F3, ITFG3, EDIL3, YTHDF1, CDC20, CCL26, TMEM79, MANSC1, DYSF, ERGIC3, GRAMD4, NCBP1, SNX11. 14 genes were down-regulated more than 50 percent in at least one cell line (PDGFB, APBB2, SATB1, MAD2L1BP, TUBB6, CEP152, KLH17, COL7A1, CKLF, PHOSPHO2, GNAT1, ABI3, TYROBP, IL10), while other 3 genes were down-regulated more than 35 percent in at least one cell line (ANG, ZIC5, JAM3). Expression of SPTA1, PAPLN, PCDH1, TMIGD2, and KRT24 was either not detectable by this method in MDA-MB-231 cells or didn't change after siRNA treatment in BT-549 cells. The foregoing results indicate that down-regulation of the 40 genes can lead to increased sensitivity to eribulin, an analog thereof, or pharmaceutically acceptable salt thereof.

TABLE 2 List of 40 overlapping genes from the screening of MDA-MB-231 and BT-549 cells. Fold changes (FC) compared to control and associated p-values are depicted. MDA-MB- Gene 231 BT-549 gene ID FC t-test FC t-test PSENEN 55851 0.70 0.03 0.39 0.00 PHOSPHO2 493911 0.56 0.04 0.44 0.02 CCL26 10344 0.71 0.02 0.45 0.03 CDC20 991 0.47 0.03 0.47 0.03 MAD2L1BP 9587 0.47 0.00 0.48 0.01 JAM3 83700 0.63 0.04 0.55 0.00 KLHL17 339451 0.65 0.04 0.57 0.00 PCDH1 5097 0.71 0.02 0.61 0.06 ABI3 51225 0.66 0.04 0.62 0.04 TMIGD2 126259 0.66 0.05 0.62 0.04 NCBP1 4686 0.72 0.04 0.63 0.02 IL10 3586 0.72 0.02 0.64 0.05 ANG 283 0.74 0.02 0.64 0.00 KRT24 192666 0.69 0.01 0.65 0.00 TMEM79 84283 0.66 0.01 0.67 0.02 PDGFB 5155 0.65 0.00 0.68 0.03 SNX11 29916 0.68 0.05 0.68 0.05 CFL1 1072 0.69 0.02 0.68 0.05 CKLF 51192 0.62 0.03 0.70 0.01 TUBB6 84617 0.73 0.01 0.71 0.01 HYAL2 8692 0.67 0.02 0.71 0.05 TYROBP 7305 0.73 0.04 0.71 0.01 APBB2 323 0.70 0.00 0.71 0.02 YTHDF1 54915 0.61 0.02 0.73 0.01 CEP152 22995 0.46 0.03 0.74 0.05 COL7A1 1294 0.73 0.03 0.75 0.05 NMU 10874 0.67 0.00 0.76 0.05 SPTA1 6708 0.38 0.03 0.76 0.02 ERGIC3 51614 0.70 0.05 0.76 0.05 SATB1 6304 0.67 0.02 0.77 0.04 MOBKL1B 55233 0.74 0.03 0.77 0.01 GNAT1 2779 0.66 0.04 0.78 0.03 ITFG3 83986 0.73 0.05 0.78 0.05 DYSF 8291 0.26 0.01 0.78 0.05 MANSC1 54682 0.65 0.03 0.78 0.05 EDIL3 10085 0.65 0.01 0.79 0.05 GRAMD4 23151 0.72 0.00 0.79 0.01 ZIC5 85416 0.69 0.03 0.80 0.05 PAPLN 89932 0.71 0.03 0.80 0.01 CYP4F3 4051 0.74 0.02 0.81 0.01

APPENDIX NUCLEIC ACID AND AMINO ACID SEQUENCES OF BIOMARKERS Gener Accession Name Gene ID NO. Name ABI3 51225 NM_016428 Homo sapiens ABI family, member 3 (ABI3), transcript variant 1, mRNA mRNA Sequence TCCTATCCACCCTCCACTCCCCTGTCCCTTGGTGACTCATCCCTGAGCTTCCCAAGGAAGCCCCCACCCT CTGCCCTTTCCTCCCGCCTTCCATGAGTGGAAAATCCACCTCCGCCCCCTATAGCAGGCCAGCCCCCTTC CTCCCCAGTCTCCGACCCCATCCCCCAGCCGACCAGTTTCCTCTCCAGGACCAGGGAGCAATCACAGCTG CCCCGACCTTGGCTTCCTCTGCTGGGTGGGATTGGGGGCTGGGCCCCCAAATGGGCCCCTGGCTTCCCCC TTCCTCTGGGCAGGGGACAGAGAGACACAGGCTCGGGGAGCAGGACTGACTTCCTCTTGTCCCGGAATGA GCATGCCTGCCCTTTGCAAGCAGGTTTGGGTCTCACGCAGAGGAAACCAAAAGCAATAAGAGGGAGGGAA GGCAGAGCAACCAATCAAGGGCAGGGTGAGACTCAAAACGAGCGGGCTCCCTGGGGAGCCAGACAGAGGC TGGGGGTGATGGCGGAGCTACAGCAGCTGCAGGAGTTTGAGATCCCCACTGGCCGGGAGGCTCTGAGGGG CAACCACAGTGCCCTGCTGCGGGTCGCTGACTACTGCGAGGACAACTATGTGCAGGCCACAGACAAGCGG AAGGCGCTGGAGGAGACCATGGCCTTCACTACCCAGGCACTGGCCAGCGTGGCCTACCAGGTGGGCAACC TGGCCGGGCACACTCTGCGCATGTTGGACCTGCAGGGGGCCGCCCTGCGGCAGGTGGAAGCCCGTGTAAG CACGCTGGGCCAGATGGTGAACATGCATATGGAGAAGGTGGCCCGAAGGGAGATCGGCACCTTAGCCACT GTCCAGCGGCTGCCCCCCGGCCAGAAGGTCATCGCCCCAGAGAACCTACCCCCTCTCACGCCCTACTGCA GGAGACCCCTCAACTTTGGCTGCCTGGACGACATTGGCCATGGGATCAAGGACCTCAGCACGCAGCTGTC AAGAACAGGCACCCTGTCTCGAAAGAGCATCAAGGCCCCTGCCACACCCGCCTCCGCCACCTTGGGGAGA CCACCCCGGATTCCCGAGCCAGTGCACCTGCCGGTGGTGCCCGACGGCAGACTCTCCGCCGCCTCCTCTG CGTCTTCCCTGGCCTCGGCCGGCAGCGCCGAAGGTGTCGGTGGGGCCCCCACGCCCAAGGGGCAGGCAGC ACCTCCAGCCCCACCTCTCCCCAGCTCCTTGGACCCACCTCCTCCACCAGCAGCCGTCGAGGTGTTCCAG CGGCCTCCCACGCTGGAGGAGTTGTCCCCACCCCCACCGGACGAAGAGCTGCCCCTGCCACTGGACCTGC CTCCTCCTCCACCCCTGGATGGAGATGAATTGGGGCTGCCTCCACCCCCACCAGGATTTGGGCCTGATGA GCCCAGCTGGGTGCCTGCCTCATACTTGGAGAAAGTGGTGACACTGTACCCATACACCAGCCAGAAGGAC AATGAGCTCTCCTTCTCTGAGGGCACTGTCATCTGTGTCACTCGCCGCTACTCCGATGGCTGGTGCGAGG GCGTCAGCTCAGAGGGGACTGGATTCTTCCCTGGGAACTATGTGGAGCCCAGCTGCTGACAGCCCAGGGC TCTCTGGGCAGCTGATGTCTGCACTGAGTGGGTTTCATGAGCCCCAAGCCAAAACCAGCTCCAGTCACAG CTGGACTGGGTCTGCCCACCTCTTGGGCTGTGAGCTGTGTTCTGTCCTTCCTCCCATCGGAGGGAGAAGG GGTCCTGGGGAGAGAGAATTTATCCAGAGGCCTGCTGCAGATGGGGAAGAGCTGGAAACCAAGAAGTTTG TCAACAGAGGACCCCTACTCCATGCAGGACAGGGTCTCCTGCTGCAAGTCCCAACTTTGAATAAAACAGA TGATGTCCTGTGACTGCCCCACAGAGATAAGGGGCCAGGAGGGATTGAAAGGCATCCCAGTTCTAAGGCT GCTGCTAATTACAGCCCCCAACCTCCAACCCACCAGCTGACCTAGAAGCAGCATCTTCCCATTTCCTCAG TACCCACAAAGTGCAGCCCACATTGGACCCCAGACACCCCTCTGCAGCCATTGACTGCAACTTGTTCTTT TGCCCATTGAAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 1) Translated protein sequence MAELQQLQEFEIPTGREALRGNHSALLRVADYCEDNYVQATDKRKALEETMAFTTQALASVAYQVGNLAG HTLRMLDLQGAALRQVEARVSTLGQMVNMHMEKVARREIGTLATVQRLPPGQKVIAPENLPPLTPYCRRP LNFGCLDDIGHGIKDLSTQLSRTGTLSRKSIKAPATPASATLGRPPRIPEPVHLPVVPDGRLSAASSASS LASAGSAEGVGGAPTPKGQAAPPAPPLPSSLDPPPPPAAVEVFQRPPTLEELSPPPPDEELPLPLDLPPP PPLDGDELGLPPPPPGFGPDEPSWVPASYLEKVVTLYPYTSQKDNELSFSEGTVICVTRRYSDGWCEGVS SEGTGFFPGNYVEPSC (SEQ ID NO: 2) ANG 283 NM_001097577 Homo sapiens angiogenin, ribonuclease, RNase A family, 5 (ANG), transcript variant 2, mRNA mRNA Sequence TCCAGGTTCACACAACTGGAACCCATCTCCAGGAACAAACAGCTGGAACCCATCTCCCGTTGAAGGGAAA CTGCCAGATTTTTGTAAGATTCTTCCTCCTGGGAGCCTGTGTTGGAAGAGATGGTGATGGGCCTGGGCGT TTTGTTGTTGGTCTTCGTGCTGGGTCTGGGTCTGACCCCACCGACCCTGGCTCAGGATAACTCCAGGTAC ACACACTTCCTGACCCAGCACTATGATGCCAAACCACAGGGCCGGGATGACAGATACTGTGAAAGCATCA TGAGGAGACGGGGCCTGACCTCACCCTGCAAAGACATCAACACATTTATTCATGGCAACAAGCGCAGCAT CAAGGCCATCTGTGAAAACAAGAATGGAAACCCTCACAGAGAAAACCTAAGAATAAGCAAGTCTTCTTTC CAGGTCACCACTTGCAAGCTACATGGAGGTTCCCCCTGGCCTCCATGCCAGTACCGAGCCACAGCGGGGT TCAGAAACGTTGTTGTTGCTTGTGAAAATGGCTTACCTGTCCACTTGGATCAGTCAATTTTCCGTCGTCC GTAACCAGCGGGCCCCTGGTCAAGTGCTGGCTCTGCTGTCCTTGCCTTCCATTTCCCCTCTGCACCCAGA ACAGTGGTGGCAACATTCATTGCCAAGGGCCCAAAGAAAGAGCTACCTGGACCTTTTGTTTTCTGTTTGA CAACATGTTTAATAAATAAAAATGTCTTGATATCAGTAAGAA (SEQ ID NO: 3) Translated protein sequence MVMGLGVLLLVFVLGLGLTPPTLAQDNSRYTHFLTQHYDAKPQG RDDRYCESIMRRRGLTSPCKDINTFIHGNKRSIKAICENKNGNPHRENLRISKSSFQV TTCKLHGGSPWPPCQYRATAGFRNVVVACENGLPVHLDQSIFRRP (SEQ ID NO: 4) APBB2 323 NM_173075 Homo sapiens amyloid beta (A4) precursor protein-binding, family B, member 2 (APBB2), mRNA mRNA Sequence GCCAAAGCCTGGAGAAGTGGAATCTCGTCAGCGCCGCTCCCTGCGCGGGACTCGCGGAACGGCACTGAGC ATGCTCAGTTGCCGGAGCCCGTTCTGGTCTCAAGTAGGAAGCTAGTGCGCTGTAACCGCATCTGATCTGG GCGCTCCGGGAAGGGCGAGACTGGAGCAGAGCCGCTGGGCGCCGGAGCCGAGGCGAGCGCCGCGCGCACC ACTGGTTGGAGTTGCTGTGGGTGAGCTGCTGTGGTCTGTAGCCAAGCATGCTGTGGTCGGATCTGCCCAG CCGTGGAACAGAAACATTTGCTGGATGGAAAATCCATAAAAGAAAGCTCCTGTGAAAAGCTGAGGCTGAC AATAATTTAAGCAAAATCAGATCGATCTCTTTGGGCTGCCTGACCTCCTTGGGTGCTTGCTATTAATTAA CAGACTTTGTGGGGAAAAAAAGGAGCTTGCCTTCTGAGCTTTGTACCAAAGACCTGGGAAAACTAACCAT CTCAGTCTTTCCTGAGGACTTGGGAACTGCCGAGGCCTCTGCCAATGTGTTGACTGTCGCTATGGGCTCA CTGTTGTCCAGGCAGCTCATATTTCAAATTATAACCTATTTCCTGCACCATTGCTGACGCCTGGTGATCC ATGTCAGAAGTACTTCCAGCTGACTCAGGTGTTGACACCTTGGCAGTGTTTATGGCCAGCAGCGGAACTA CAGACGTCACAAATCGGAACAGCCCAGCCACACCACCAAACACCCTTAACCTCCGATCCTCCCACAATGA ACTGTTGAACGCTGAAATAAAACACACAGAAACCAAGAACAGCACACCTCCCAAATGCAGGAAAAAATAT GCACTAACTAACATCCAGGCGGCCATGGGCCTCTCGGATCCAGCTGCACAGCCCCTGCTGGGAAATGGCT CTGCCAACATCAAGCTGGTGAAAAATGGGGAGAACCAGCTCCGTAAGGCTGCAGAGCAAGGGCAGCAGGA CCCCAACAAAAACCTGAGCCCCACTGCAGTCATCAACATAACTTCTGAGAAGTTAGAGGGTAAAGAGCCC CACCCACAGGATTCCTCGAGCTGTGAGATTTTACCCTCCCAGCCCAGGAGAACTAAGAGCTTCCTAAATT ACTATGCAGATCTGGAAACCTCAGCCAGAGAACTAGAGCAGAACCGAGGCAATCACCATGGGACTGCGGA AGAGAAATCCCAGCCAGTCCAGGGCCAGGCCTCCACCATCATTGGGAATGGCGATTTGCTGCTGCAGAAA CCAAACAGACCCCAGTCCAGCCCTGAAGACGGCCAAGTAGCCACAGTGTCATCCAGCCCAGAAACCAAGA AGGATCATCCGAAAACAGGGGCCAAAACCGACTGTGCACTGCACCGGATCCAGAACCTGGCACCGAGCGA TGAGGAGTCCAGCTGGACAACGTTGTCCCAAGACAGTGCCTCACCCAGCTCCCCGGATGAAACAGATATA TGGAGTGATCACTCATTTCAGACTGATCCAGATTTGCCGCCTGGCTGGAAAAGAGTCAGTGACATTGCCG GGACCTATTATTGGCACATCCCAACAGGAACGACTCAGTGGGAACGGCCCGTCTCCATCCCAGCAGATCT CCAGGGTTCTAGGAAAGGGTCACTTAGTTCTGTAACGCCATCTCCCACCCCAGAGAACGAGGATTTGCAT GCAGCCACTGTTAACCCGGACCCCAGTTTAAAAGAGTTTGAAGGAGCAACCCTACGCTATGCATCTTTGA AACTCAGAAATGCCCCACACCCTGATGATGATGATTCTTGTAGTATCAACAGTGACCCAGAAGCCAAGTG TTTTGCTGTGCGTTCTCTGGGATGGGTAGAGATGGCAGAAGAGGACCTCGCCCCCGGTAAAAGTAGTGTT GCGGTCAACAACTGCATCAGGCAACTTTCCTACTGCAAAAATGACATCCGAGACACAGTCGGGATTTGGG GAGAGGGGAAAGACATGTACCTGATCCTGGAGAATGACATGCTCAGCCTGGTGGACCCCATGGACCGCAG CGTGCTGCACTCGCAGCCCATCGTCAGCATCCGCGTGTGGGGCGTGGGCCGCGACAATGGCCGGGATTTT GCTTATGTAGCAAGAGATAAAGATACAAGAATTTTGAAATGTCATGTATTTCGATGTGACACACCAGCAA AAGCCATTGCCACAAGTCTCCACGAGATCTGCTCCAAGATTATGGCTGAACGGAAGAATGCCAAAGCGCT GGCCTGCAGCTCCTTACAGGAAAGGGCCAATGTGAACCTCGATGTCCCTTTGCAAGATTTTCCAACACCA AAGACTGAGCTGGTCCAGAAGTTCCACGTGCAGTACTTGGGCATGTTACCTGTAGACAAACCAGTCGGAA TGGATATTTTGAACAGTGCCATAGAAAATCTTATGACCTCATCCAACAAGGAGGACTGGCTGTCAGTGAA CATGAACGTGGCTGATGCCACTGTGACTGTCATCAGTGAAAAGAATGAAGAGGAAGTCTTAGTGGAATGT CGTGTGCGATTCCTGTCCTTCATGGGTGTTGGGAAGGACGTCCACACATTTGCCTTCATCATGGACACGG GGAACCAGCGCTTTGAGTGCCACGTTTTCTGGTGCGAGCCTAATGCTGGTAACGTGTCTGAGGCGGTGCA GGCCGCCTGCATGTTACGATATCAGAAGTGCTTGGTAGCCAGGCCGCCTTCTCAGAAAGTTCGACCACCT CCACCGCCAGCAGATTCAGTAACCAGAAGAGTCACAACCAATGTAAAACGAGGGGTCTTATCCCTCATTG ACACTTTGAAACAGAAACGCCCTGTCACCGAAATGCCATAGCTGCACATGCAAAAGGACTCGGCTATTTA CCTGAAGATTGACTAGCTACACTAAAGAAAATGAACTCCGCCATCCGACCTTCCATCCAGTTGCTGATGC TTTGTCTTCAGAGAATTTACCCTTAACCAAGCAGTGTTAGACAAGCATGTTCTCTCGTCTTGCCACCATC ATGTGATATGAAAAGAAGCATGAATAATTTTTTTTGCTGTAAGTTACATCATGCGCAGTGGAAGGTCTTT TTCTTATTGTAAATATTGTGAACATTACTTAACTTCACACACACACAGAGAAGAGTGTGGCCCCACCCCT CCTAGTGAACTAACGCTGCGTCCTTGGAATGAATGATGCGTGAGTTAGTTTCACTGTCTTCTTGGCTGGA CCTGTCACAAGCAACCTTTAAGTCCTACAGCACTTTGCCCTGTTTTCAACATTGGAGTAGGCACTGCATA GCAGATACCATTGAATTGCTGTAAAAATAGGATGGCGAGTTTGTGTTTTAATTTTTCATAAAATTGAACC TGTTGGTTGACAAAATTGGCTGTTGGCATCAGTATAGAAACCAACTGGCAGCTTTCCCTGACAAGCTCTT TGACACATGGACACCATTTCATGTCTACAGCTGTTTGTGGGATGTTGGAAAAAAATGAAACTTCAAAATT GATGAAAAACTAAATTCGAGGAATTAAAATCGAACAAAACATAGCCTTTCTTTTCCGATGGTTTTCAAAC TGATTATTTTTAAAAGAGATTAATAAAATCATAATGCATTTTGGGTGGGACATATTTCAAACTTCTGCCT TATATTGTACGGTGCAGCTAGAGAATTATAGTTCACTATGGCCATTCTCTACATAAACATTAAGATGAAA TACTCCTCATCAGCCTTTCATCCTTAGTTTGAGAATTAGCTGATATGCAATTTGAAGTTGAGGAAATATC ATTGATATTTCTATCATGCACGATTATTTTAGATTTCTACCACCGTGTGATTTTTGCTAGTCCATGTGCT AGAGGTAAACGTTCTGCTGGAATTCTGCATCCAGCTCTATCCCCCTCTGATGCTTTTTGCCCAGAAAGCT GTCTGTCCATCATGTATTGTCCATGGCAACAAATTACATTAGGTTGAACCTTTCCTTGATTTTATGTATT TAATATTAGAATTTGTTGGACTCAACTAGATATATTTTTTAATTTATATTTTTTCCATTTTACTTTGAAG ATTTGAAATGTTCATACCTGAGCAAAGTCTACACAGGAGTAATGGACTGTTTAACAAGTTTCCCAAAACA GCATTTTCCTGCTCCTTCGTATGTAGGTGAGAAACTTAGCTGGAAAGACATACAAATTTAGACTCTCGTT GACATTGTCGTTTTAAAAGGAAGTTGCTAAGGCGATCAATCTCAATATTAGTCTTGTTTACTTCTTCTTA ATGTCAAAATTAACATTTACAACATCCAATTATAAAAGTAATGCTTTATGTTTATACACTGCTATGTACT TGTCAAAATGGTTTCCACATTCTTATCACATCTGAGCCTTACCAGGTAGAGAAGGTACTAAATACACTTT AGAAGTAAAAATATGAAGTACCGAGAGGCTAAACCCACTGGCCTAAGATCTCACCAAAGTTCATGAAAAC CAGGACTAGGACCCACGGCTCCCAAAGCCCGTTCTTGCTGTGTTGTGCTGCCTCCATATCCGTCAGGAAG AGCCTTTCCAGAATGATTCTGGGCATATACTAAGAAGAGCAGGTATGGAAAGATCTATTGTCAGGGAATC TTAGAATTCCCTACACGAGTGGGAGAAAGATGTCCAAATTCCTTACGCAGTGGTATTCATGATGGTGCCC TATCTAAGTCCAGGACTGTTTTCCTACAGCGTGCCTCAAAAGTGTTGTAGAGGGCAGGATTCTACATTCA CAGCCTGTTCCATCTACGAGATTTTCCAGATGCTACTTGTGGTAGACATTCCTAACTCATGGTACTTAGC CACCAGAGATCATGATGGAATGAGTGGGTGGCTTTTCTACCTGCCATTCCCTCAGAATTCATGAGGGGTG GGGGACAGGGGGACCGGAATTGTCTTAGCACCCCAATGTTATGACAAAACTATGCTACTTTAGAAACGCA GTCTGTTTTTCACCAATTGACATACTACTGATCTGAAGTAACCAGTGCCATCATAAGAAATTACTGCATT AAGAAAATCCTTGCTGTGCCCTTTGAAAAGCTGTTCAGAAATCATTTACAGTGATCTTTCATCTCGGTCG CTGTAGTGAAACATTTTAGTGTGATAAATTTCAAAATTCTAAACAAATTACCCACTTTTATATTGGAAAT CTCTACCAGAACTCCCTCTTCATTTTTTAAGGCATACATTTGCTTGTTTTCAAGATCAAGAATTCTGAGC TAGCTTTAAGTAGCAAACTGATTTATATGTGCAATTATAGGATGCATTAAGATGAATGATAGCCTTTACA TATTGAAAACTTTGCAGACGTTTTGTTTTGAAAATGGCATTGTATAGTAAATGCAAATTAATTTTGTAAA ATTATGTTAAAGAGTATGTTCAGACACTTTCTGCCATGGCCAAAAAGTATGTATGAAAGTATGTGTGTAT TTGTTTGTAAAAGGATGCCAATGTTTTACCTGATATCTTAGTGACACTTCAGTTATCTATGCATTCTTTA GATCTGTGATTCGGTAAACAGGCAGCCATGTTCACGATGCCTTCTATGTCTTACCATATTTTTAATTAAC CTGTTAAATACAGCTTAAAATATTTTTATTTTATTTATTCTATTTTTACTGAAATATACTGCATTATTGT GTTAATGTATTATCTTTCCTGGATATTATCTCCCAGTGTATCCAGATCTAAGTAATCTCAGTGAACTATA CATTGCCTAAAAAGTGGTTTTGTAATGATTTGTAGTCACATTTCTATTGGGATATGTAGAAGAAAAGGCA AAATGCTTAAAGTTCCTTTTATTTTTTAAAAGCAGCTAGATAGACACAGACTTGCCACCTCATACATCTG CTCCTTGGCAACATCAAGGGGAACGACTAGCCAACATGCCTATGGCTAAAAACTTTCCTTTGCAGACTAA AGCACTGCTTGGTGCTTCGTTTTTCTACCCTTCACAACATGTGTGATTTCATCTAAGAGATATATACATG TACACATGCCCTTTGTTTCCACCTGGATACAAGATCACTCATAGCTAATTAGGACCATTGTTTTTTGTTC ATCTGTCTTGTTGCATGAAGGGACATTAGACCCATTTCCATTAAAATAAGTTCTTGGTGATAAACTGTGG CACTGCTACTTCTTTTTAAATCCACTTTATGATTTCAAGATGGACACTTGTAAGATGACTCGACACAAGG CCATTGCCTGGAAGCCCCAGAGCTTTCCTCTGTTTGTATGGCCCGTTCATGTCCCAGGCATTGCAACACA AACTCCTCAAGATTTCACCACAACATGACAAGCATTTTCCTAACTGATATTAGCACAATTTAACTAATAA GCCCCTTCGCTCTCTAGTTGGCCAGGCTTAACCTAATACACATCTAACGTGTGTGCCACACGGCCAGTAG AAAGTTTAACTTCAGCTTCAGGGCAAAGATACCCACTCACACCGTGTCAACGCAAGCAGTAGTTCCTGGC CTCCAGAGCAGCTTACTTCCCCTGAAAGAACGCTTTGTTTTCCTTTATGCCCTTTTCCTGTTGACCACTT TTACACATTTAAATGTAATTTGTTGTGAGAATAAATTTAGCTGCATAAAACGTTCGGCTCATTTATCTGA CATCTTAGTCACATATACAAGGAATAGAAATAGAAACTCGGTGTCTCTAGTTATTTTTAAATTATTCTTA CCTCAGACTTCTTAGAAATCACTTTAGTAATGGAGCATTTTGCTTTGATTAGTTACTACATATTTCTGCC TGGTAAGAACTAGGAAGTAACTTCAAATTTTGAGTAATCACCCTGTACTTATTTGGTGATCAGGAAGGCC AGCTGGCCTTCCGGACATAGAAGCCTATTTAGTCACCAACTCGAGTCTTTTGTAAGCGGTCTTGCTAGGA TTGTGATATTTTAGCACGAAGAAGTTTATCACTTCCTTTAAGAACCTGACATCAAAGAATAAAGAATAGA GGTGTACACACACTAAATCCAAAATGAAAGGTAACTAGAGAAATCAGTTGAATCTGGTTTAGCTTAACTG TTAGGCGCAGGAAGGCAGATAAACAGAATTTAAAGTATGTCCCCGCTTTTTGTTCATCTTGCACTTCCAC AGTGGTTTCTCTCTAGTCAGTAACAAAATTTCATTATGGTTTCAGGCATTATATGGTGGTAAATAATTTC AGATTAAAAATGTGTTTGCTATTGGAGTATCTGAATACTAGTAATTTCATTATTTAGAATTTTGCAGCAC TTTTATCTCAAGAAGAAGTCCAAGAATGTAAAATGCCAAATGAAACATGTCAGTGGAATCAATATTCTCC TTCATTAGAATTCCCTCATATTGCTTTTTTTTTTTTTCTTCAGACAGAGGAGTCTTACTCTGGAGTGCAG TGGTGTAATTTCAGCTCACCACAACCTCCACCTCCCAAGTTCAAGCAATTCTCGCCTCAGCCTCCTGAGT AGCTGGGATTACAGGCATGCACCGCCACGCCTGGCCAATTTGTATATTTTTAGTAGAGACAGGGTTTCGC CACGTTGGCCAGGCTGGTCTCGAACTCCTGACCTCAGGTGATCCGCCCGCCCCAACCTCCCAAAGTATGT GAGCCACCACGTCCGGCCTCATATTGCTTTTATCCAAAATTCTTTTCCCTTTTCACTCTACCAAAGTATT TAAATAATCCTGTCCTTCATAGAAGATTCTCAAAGAAGAAAACTGCAGTGTAATTAATGAATGGTTTAAT TCAGAATCTTCATATACTTCTAAAGAGAAAAATAATTTAGTGCCAAATGCATGTTAGGAGATAATCAATG TAAGTGGCAACAAATTGTGACTTCACATGCTACTGTAGAGATCAGAAAATTATCCTAAACTATTCCATAA CAATGAGACAACATCACAGAAAATACACTTGAAAATAAAAATCTCAAGACCAGCTACTTCTGGACAATGG AATACTTTTCAGTCTGGTATGGTGGAGGGCCCGAAAAGGATAAGGGATTCTTATGATACACAATGGGATT CTTTACTGAACAATATGTTAAATTAAGCTGCACCGCCTTCCTTGAGGCATGGACTACCCTAACCAACCAG ATAGAAATCTGGGTGGGATAAGAGGATGAGCCACACGCTATAATTTTAGGGCAAGGAGATAGTGTTTGAT TTTCAAAATCAGCAAAATAAGCTGAGCACTTTATATCTTTCTGTACAAGAGTGATAACATGAAGAATTCT TCTTCAGGGATTTAAAATACAATAAGCCTGGTTCAACTATAAAAAGTCTTGTTTCCTTTCTTCATTGACA CTTTTTTTTTTTTTTTTTTTTTTTTGAGGCAAGGTCTCACTCTGCTTCCCAGGCTGGAGTGCAGTGGGGC AATATTGGCTCACTGCAACCTGCACCTCCTGGACTCAAGAGATCCTCGTACCTCAGCCTCCTAAGTAGCT GGGACTACAGGCGTGTCCCACCACACCCAGCTAATTTTTGTATTTTTTGTAGAGATGGGGTTTTGGGGTT TCGCCATGTTGTCCAGGCTCGTCTGGAACTCCGGTGCTCAAGTGGCGTGCCCACCTCAGCCTCCCAAACT GCTGAGATTACAGATGTGAGCCACTGCACCCAGCCCACTGACACGTTTTACTGATAAATGTAAATCTAAG CTAAAATAAAAATAATGTATTACCGCTATAATACAATTCACCATTCTCTTTTCTCACTTCAAGTAAGAAA GTAAAAATAGAATATCAGAGCTGAAGTAGACCTAAGTATTCATCTTGAAGAAGATAATATTCTAAAAATC ATGCCACCTGAATTGAGCATTTAGGAATTTATGTAACATTTCTATACAACTGAATTGCAAAAATAAAACT TTAAATTCAAACTTTAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 5) Translated protein sequence MSEVLPADSGVDTLAVFMASSGTTDVTNRNSPATPPNTLNLRSS HNELLNAEIKHTETKNSTPPKCRKKYALTNIQAAMGLSDPAAQPLLGNGSANIKLVKN GENQLRKAAEQGQQDPNKNLSPTAVINITSEKLEGKEPHPQDSSSCEILPSQPRRTKS FLNYYADLETSARELEQNRGNHHGTAEEKSQPVQGQASTIIGNGDLLLQKPNRPQSSP EDGQVATVSSSPETKKDHPKTGAKTDCALHRIQNLAPSDEESSWTTLSQDSASPSSPD ETDIWSDHSFQTDPDLPPGWKRVSDIAGTYYWHIPTGTTQWERPVSIPADLQGSRKGS LSSVTPSPTPENEDLHAATVNPDPSLKEFEGATLRYASLKLRNAPHPDDDDSCSINSD PEAKCFAVRSLGWVEMAEEDLAPGKSSVAVNNCIRQLSYCKNDIRDTVGIWGEGKDMY LILENDMLSLVDPMDRSVLHSQPIVSIRVWGVGRDNGRDFAYVARDKDTRILKCHVFR CDTPAKAIATSLHEICSKIMAERKNAKALACSSLQERANVNLDVPLQDFPTPKTELVQ KFHVQYLGMLPVDKPVGMDILNSAIENLMTSSNKEDWLSVNMNVADATVTVISEKNEE EVLVECRVRFLSFMGVGKDVHTFAFIMDTGNQRFECHVFWCEPNAGNVSEAVQAACML RYQKCLVARPPSQKVRPPPPPADSVTRRVTTNVKRGVLSLIDTLKQKRPVTEMP (SEQ ID NO: 6) CCL26 10344 NM_006072 Homo sapiens chemokine (C-C motif) ligand 26 (CCL26), mRNA mRNA Sequence CTGGAATTGAGGCTGAGCCAAAGACCCCAGGGCCGTCTCAGTCTCATAAAAGGGGATCAGGCAGGAGGAG TTTGGGAGAAACCTGAGAAGGGCCTGATTTGCAGCATCATGATGGGCCTCTCCTTGGCCTCTGCTGTGCT CCTGGCCTCCCTCCTGAGTCTCCACCTTGGAACTGCCACACGTGGGAGTGACATATCCAAGACCTGCTGC TTCCAATACAGCCACAAGCCCCTTCCCTGGACCTGGGTGCGAAGCTATGAATTCACCAGTAACAGCTGCT CCCAGCGGGCTGTGATATTCACTACCAAAAGAGGCAAGAAAGTCTGTACCCATCCAAGGAAAAAATGGGT GCAAAAATACATTTCTTTACTGAAAACTCCGAAACAATTGTGACTCAGCTGAATTTTCATCCGAGGACGC TTGGACCCCGCTCTTGGCTCTGCAGCCCTCTGGGGAGCCTGCGGAATCTTTTCTGAAGGCTACATGGACC CGCTGGGGAGGAGAGGGTGTTTCCTCCCAGAGTTACTTTAATAAAGGTTGTTCATAGAGTTGACTTGTTC AT (SEQ ID NO: 7) Translated protein sequence MMGLSLASAVLLASLLSLHLGTATRGSDISKTCCFQYSHKPLPW TWVRSYEFTSNSCSQRAVIFTTKRGKKVCTHPRKKWVQKYISLLKTPKQL (SEQ ID NO: 8) CDC20 991 NM_001255 Homo sapiens cell division cycle 20 homolog (S. cerevisiae) (CDC20), mRNA mRNA Sequence GAGGCGTAAGCCAGGCGTGTTAAAGCCGGTCGGAACTGCTCCGGAGGGCACGGGCTCCGTAGGCACCAAC TGCAAGGACCCCTCCCCCTGCGGGCGCTCCCATGGCACAGTTCGCGTTCGAGAGTGACCTGCACTCGCTG CTTCAGCTGGATGCACCCATCCCCAATGCACCCCCTGCGCGCTGGCAGCGCAAAGCCAAGGAAGCCGCAG GCCCGGCCCCCTCACCCATGCGGGCCGCCAACCGATCCCACAGCGCCGGCAGGACTCCGGGCCGAACTCC TGGCAAATCCAGTTCCAAGGTTCAGACCACTCCTAGCAAACCTGGCGGTGACCGCTATATCCCCCATCGC AGTGCTGCCCAGATGGAGGTGGCCAGCTTCCTCCTGAGCAAGGAGAACCAGCCTGAAAACAGCCAGACGC CCACCAAGAAGGAACATCAGAAAGCCTGGGCTTTGAACCTGAACGGTTTTGATGTAGAGGAAGCCAAGAT CCTTCGGCTCAGTGGAAAACCACAAAATGCGCCAGAGGGTTATCAGAACAGACTGAAAGTACTCTACAGC CAAAAGGCCACTCCTGGCTCCAGCCGGAAGACCTGCCGTTACATTCCTTCCCTGCCAGACCGTATCCTGG ATGCGCCTGAAATCCGAAATGACTATTACCTGAACCTTGTGGATTGGAGTTCTGGGAATGTACTGGCCGT GGCACTGGACAACAGTGTGTACCTGTGGAGTGCAAGCTCTGGTGACATCCTGCAGCTTTTGCAAATGGAG CAGCCTGGGGAATATATATCCTCTGTGGCCTGGATCAAAGAGGGCAACTACTTGGCTGTGGGCACCAGCA GTGCTGAGGTGCAGCTATGGGATGTGCAGCAGCAGAAACGGCTTCGAAATATGACCAGTCACTCTGCCCG AGTGGGCTCCCTAAGCTGGAACAGCTATATCCTGTCCAGTGGTTCACGTTCTGGCCACATCCACCACCAT GATGTTCGGGTAGCAGAACACCATGTGGCCACACTGAGTGGCCACAGCCAGGAAGTGTGTGGGCTGCGCT GGGCCCCAGATGGACGACATTTGGCCAGTGGTGGTAATGATAACTTGGTCAATGTGTGGCCTAGTGCTCC TGGAGAGGGTGGCTGGGTTCCTCTGCAGACATTCACCCAGCATCAAGGGGCTGTCAAGGCCGTAGCATGG TGTCCCTGGCAGTCCAATGTCCTGGCAACAGGAGGGGGCACCAGTGATCGACACATTCGCATCTGGAATG TGTGCTCTGGGGCCTGTCTGAGTGCCGTGGATGCCCATTCCCAGGTGTGCTCCATCCTCTGGTCTCCCCA TTACAAGGAGCTCATCTCAGGCCATGGCTTTGCACAGAACCAGCTAGTTATTTGGAAGTACCCAACCATG GCCAAGGTGGCTGAACTCAAAGGTCACACATCCCGGGTCCTGAGTCTGACCATGAGCCCAGATGGGGCCA CAGTGGCATCCGCAGCAGCAGATGAGACCCTGAGGCTATGGCGCTGTTTTGAGTTGGACCCTGCGCGGCG GCGGGAGCGGGAGAAGGCCAGTGCAGCCAAAAGCAGCCTCATCCACCAAGGCATCCGCTGAAGACCAACC CATCACCTCAGTTGTTTTTTATTTTTCTAATAAAGTCATGTCTCCCTTCATGTTTTTTTTTTAAAAAAAA AAAAAAAAAAAAAAAAA (SEQ ID NO: 9) Translated protein sequence MAQFAFESDLHSLLQLDAPIPNAPPARWQRKAKEAAGPAPSPMR AANRSHSAGRTPGRTPGKSSSKVQTTPSKPGGDRYIPHRSAAQMEVASFLLSKENQPE NSQTPTKKEHQKAWALNLNGFDVEEAKILRLSGKPQNAPEGYQNRLKVLYSQKATPGS SRKTCRYIPSLPDRILDAPEIRNDYYLNLVDWSSGNVLAVALDNSVYLWSASSGDILQ LLQMEQPGEYISSVAWIKEGNYLAVGTSSAEVQLWDVQQQKRLRNMTSHSARVGSLSW NSYILSSGSRSGHIHHHDVRVAEHHVATLSGHSQEVCGLRWAPDGRHLASGGNDNLVN VWPSAPGEGGWVPLQTFTQHQGAVKAVAWCPWQSNVLATGGGTSDRHIRIWNVCSGAC LSAVDAHSQVCSILWSPHYKELISGHGFAQNQLVIWKYPTMAKVAELKGHTSRVLSLT MSPDGATVASAAADETLRLWRCFELDPARRREREKASAAKSSLIHQGIR (SEQ ID NO: 10) CEP152 22995 NM_014985 Homo sapiens centrosomal protein 152 kDa (CEP152), mRNA mRNA Sequence GCCCACCGGGCGAGCTTCTAGTCGGCGATTGAAGGATGCGAGTGCTCCTTAAGGGCCTCCGCCCCGTGAG TTCGGTTGTGACTAGGAAGGAGCTAGTGGACTAGAGCCAGGGTAAGGGGATCTGCTAGAAGTTGGTCTTC CGCCAGGACTAGAGTTTCCTCGCGGTAACAGCCTCCGTGGCCTCCGGAGGACCATGTCATTAGACTTTGG CAGTGTGGCACTACCAGTGCAAAATGAAGATGAAGAGTATGACGAAGAGGACTATGAAAGAGAGAAAGAG TTGCAGCAGTTACTCACAGACCTTCCCCATGACATGCTGGATGACGACCTCTCCTCTCCAGAGCTCCAGT ATTCGGACTGCAGCGAGGATGGCACAGACGGACAACCACATCATCCTGAGCAATTGGAGATGAGCTGGAA TGAGCAAATGCTGCCCAAATCTCAAAGTGTAAATGGCTATAATGAAATTCAGAGTTTATATGCTGGAGAA AAATGTGGTAATGTCTGGGAAGAAAATAGAAGTAAAACTGAAGACCGACATCCTGTGTACCATCCTGAAG AAGGTGGAGATGAAGGTGGAAGTGGTTATAGTCCTCCAAGTAAATGTGAACAGACTGATTTATATCACCT TCCTGAAAACTTTAGGCCATATACCAATGGTCAGAAGCAGGAATTTAATAACCAAGCAACCAATGTAATT AAATTTTCAGATCCTCAATGGAACCATTTTCAGGGTCCCAGTTGTCAAGGTTTGGAACCGTATAATAAAG TGACATATAAACCTTATCAGTCTTCTGCCCAGAATAATGGCTCACCAGCCCAGGAGATAACAGGAAGTGA CACATTCGAAGGCCTGCAACAACAATTTTTAGGAGCTAATGAGAACTCTGCAGAAAATATGCAGATTATT CAACTTCAGGTTCTTAACAAAGCAAAAGAGAGACAACTGGAGAACTTAATTGAAAAGTTAAATGAAAGTG AACGTCAAATTCGATATCTGAATCACCAGCTTGTAATAATAAAAGATGAAAAGGATGGTTTGACTCTCAG CCTTCGAGAATCACAGAAACTCTTTCAGAATGGAAAAGAAAGAGAGATACAGCTTGAAGCTCAAATAAAA GCACTGGAGACTCAGATACAAGCATTAAAAGTCAATGAAGAACAGATGATCAAGAAGTCCAGAACAACTG AAATGGCTCTGGAAAGCTTGAAGCAGCAGCTGGTGGACCTTCATCATTCTGAATCACTTCAACGAGCTAG AGAACAGCATGAGAGCATTGTTATGGGCCTCACAAAGAAGTACGAAGAGCAAGTATTGTCCTTACAAAAG AATTTGGATGCCACAGTCACCGCACTTAAAGAACAGGAAGACATTTGCTCTCGTCTGAAAGATCACGTGA AACAACTGGAAAGGAATCAAGAAGCAATCAAGTTAGAAAAGACTGAGATCATTAATAAGTTGACAAGAAG TCTAGAGGAGAGTCAAAAGCAGTGTGCCCACTTGTTGCAGTCCGGGTCAGTACAAGAGGTGGCTCAGCTA CAGTTCCAGCTGCAGCAAGCACAGAAGGCACATGCTATGAGTGCAAACATGAACAAGGCTTTGCAAGAAG AATTAACAGAACTAAAAGATGAAATTTCTCTCTATGAATCTGCTGCAAAACTAGGAATACATCCAAGTGA CTCAGAAGGAGAATTAAATATAGAACTCACTGAATCGTATGTGGATTTGGGTATTAAAAAGGTCAACTGG AAAAAATCCAAAGTTACCAGCATTGTACAAGAAGAAGACCCAAATGAAGAGCTTTCAAAAGATGAGTTCA TTCTGAAGTTAAAGGCAGAAGTACAGCGTTTGCTGGGTAGCAACTCAATGAAGCGTCATCTGGTGTCTCA GTTACAAAATGACCTCAAAGACTGTCATAAGAAAATTGAAGATCTCCACCAAGTGAAGAAGGATGAAAAA AGCATTGAGGTTGAGACTAAAACAGATACCTCAGAAAAACCAAAGAATCAATTATGGCCTGAGTCTTCTA CTTCTGATGTTGTCAGAGATGATATTCTGCTGCTTAAAAATGAAATTCAAGTTTTACAACAACAAAATCA GGAACTTAAAGAAACTGAAGGAAAACTGAGAAATACAAATCAAGACTTATGTAATCAAATGAGACAAATG GTACAAGATTTTGACCATGACAAACAAGAAGCTGTGGATAGGTGTGAAAGGACTTATCAGCAGCACCATG AAGCCATGAAAACTCAAATACGTGAAAGCCTATTAGCAAAGCATGCTTTGGAGAAGCAGCAGCTCTTTGA GGCTTATGAGAGAACTCATTTGCAACTGAGGTCTGAGTTGGATAAGTTGAATAAGGAGGTGACTGCTGTG CAGGAATGTTACCTAGAAGTGTGCAGAGAGAAGGATAATCTAGAATTGACTCTCAGGAAGACCACTGAAA AGGAGCAACAGACTCAGGAGAAGATCAAAGAAAAACTCATTCAACAGCTTGAAAAGGAGTGGCAGTCTAA GCTGGATCAAACTATAAAGGCAATGAAAAAGAAGACCTTAGATTGTGGCAGCCAAACTGACCAAGTAACC ACCAGTGATGTTATTTCCAAGAAAGAGATGGCAATTATGATAGAAGAGCAGAAGTGCACAATCCAGCAAA ACTTAGAACAAGAGAAGGACATAGCCATCAAGGGGGCTATGAAGAAACTCGAAATTGAATTGGAACTCAA ACATTGTGAAAATATTACCAAACAGGTAGAAATAGCTGTGCAAAATGCTCATCAGCGATGGCTGGGAGAA CTACCAGAGCTGGCAGAGTATCAAGCACTTGTGAAGGCAGAACAGAAAAAGTGGGAAGAACAGCATGAGG TCTCTGTGAACAAAAGGATATCATTTGCTGTTTCTGAAGCTAAAGAGAAATGGAAGAGTGAGCTTGAAAA TATGAGGAAAAATATACTTCCTGGAAAGGAATTGGAAGAGAAGATTCATTCTCTTCAGAAGGAACTTGAG TTAAAGAACGAAGAAGTCCCTGTGGTCATCAGGGCTGAGTTAGCTAAGGCTCGGAGTGAATGGAACAAAG AAAAGCAAGAAGAAATCCACAGAATCCAAGAACAAAATGAGCAAGATTACCGGCAATTTTTAGATGATCA CCGAAATAAAATTAATGAGGTGCTTGCGGCAGCTAAAGAAGACTTTATGAAACAAAAAACTGAACTACTT CTTCAGAAGGAGACAGAATTACAAACTTGTCTAGACCAGAGTCGTAGAGAATGGACTATGCAGGAAGCCA AGCGGATCCAACTGGAAATCTATCAGTATGAGGAAGACATCCTGACTGTACTTGGGGTTCTTTTAAGTGA TACCCAAAAGGAGCACATCAGTGATTCTGAGGACAAGCAGCTTTTGGAAATCATGTCGACTTGTTCTTCA AAATGGATGTCTGTGCAATATTTTGAAAAACTAAAGGGCTGCATACAGAAAGCATTTCAAGATACACTTC CTCTGCTTGTAGAAAACGCTGACCCAGAATGGAAAAAGAGAAATATGGCCGAGCTCTCTAAGGATTCTGC CAGCCAGGGCACTGGCCAAGGAGACCCTGGACCTGCTGCTGGACACCATGCTCAGCCCTTGGCCTTACAA GCAACAGAAGCAGAAGCTGAAGAGAATAATAAAGTTGTTGAAGAATTAATAGAAGAAAACAACGACATGA AGAATAAATTGGAAGAATTGCAAACACTTTGTAAAACACCACCAAGGTCATTGTCAGCAGGGGCCATTGA AAATGCTTGCCTGCCATGCAGTGGGGGAGCCTTGGAAGAACTTCGTGGGCAGTACATTAAAGCTGTAAAA AAAATTAAATGTGACATGCTTCGTTATATTCAGGAGAGTAAGGAACGAGCTGCAGAAATGGTAAAAGCAG AGGTACTGCGAGAACGTCAAGAAACCGCCCGAAAGATGCGCAAATATTATTTGATTTGCCTCCAACAGAT TTTGCAGGATGATGGAAAAGAAGGGGCTGAGAAAAAGATTATGAATGCTGCTAGCAAACTTGCTACAATG GCAAAATTACTGGAAACACCTATTTCTAGTAAGTCCCAAAGCAAAACTACACAGTCAGCACTGCCCCTAA CTTCAGAGATGCTGATTGCAGTTAAAAAATCAAAAAGAAATGATGTGAATCAGAAAATACCATGTTGTAT TGAAAGCAAATCAAATAGTGTAAACACCATCACCAGAACTCTGTGCGAACAAGCTCCCAAGAGGAGGGCA GCTTGTAACTTACAAAGGCTGTTAGAGAACTCAGAGCATCAGAGCATAAAGCATGTGGGATCCAAAGAGA CACATTTGGAATTCCAGTTTGGGGATGGTAGTTGCAAGCACCTAAACAGTTTGCCAAGGAATGTTTCTCC TGAGTTTGTTCCTTGTGAAGGTGAAGGAGGCTTTGGTTTGCACAAGAAGAAAGACCTACTCAGTGATAAT GGTTCTGAATCACTTCCGCATTCAGCTGCATACCCCTTTCTTGGAACCTTAGGAAATAAACCCTCACCTA GATGTACCCCTGGTCCTTCTGAATCAGGATGCATGCATATAACCTTTCGCGATTCTAATGAAAGACTTGG TTTAAAAGTATATAAATGCAATCCACTAATGGAAAGTGAAAATGCTGCATCTGAGAAAAGTCAAGGTTTG GATGTTCAGGAACCTCCAGTAAAAGATGGAGGGGACCTTAGTGACTGCTTGGGCTGGCCTTCCAGCAGTG CAACCTTATCCTTTGACAGTCGTGAAGCATCATTTGTACATGGTAGGCCACAAGGAACTTTGGAAATACC AAGTGAATCTGTTAAATCCAAACAGTTTTCACCATCCGGTTATCTTTCAGATACAGAGGAAAGTAATATG ATTTGTCAAACAATGAAATGTCAGCGTTATCAAACTCCATACCTGTCAGAAGAAACCACGTATTTGGAGC CAGGAAAGATCAGTGTGAATTGTGGACACCCATCTCGTCATAAGGCTGATAGATTAAAGTCAGATTTCAA AAAACTGAGCAGTACATTACCATCTTCAGTGTGTCAGCAGCCTTCAAGAAAATTAATTGTTCCGCTATCT AGCCAACAAGATAGTGGCTTTGATAGCCCATTTGTTAATCTAGACTAATTATGGTACAGTATTTAAGAAG AATCATTAATATATTAACAAAAATGGAAGGGAAGACCTCATACTGAAAAAAATTGTGAGCCCTGCCTCTT TTGAGATGTTTTAATAACATCTGTTATATAAGTAAAGCATTCTTCTAAAATTGCTTGAGATATTTATGTT GCCTTAATATTCCAAAGGCCTGATGGTGTATGTATAATCTGCTTTTGTGTGGTGCTTATTTTTGGTTTCT AAACCATCTATTTTTATACTTATAAATTGACTCACTCTGCAGTGTTAACTTATTTAAATAAACTTGCATA TGGTCTGTAAAAAAAAAA (SEQ ID NO: 11) Translated protein sequence MSLDFGSVALPVQNEDEEYDEEDYEREKELQQLLTDLPHDMLDD DLSSPELQYSDCSEDGTDGQPHHPEQLEMSWNEQMLPKSQSVNGYNEIQSLYAGEKCG NVWEENRSKTEDRHPVYHPEEGGDEGGSGYSPPSKCEQTDLYHLPENFRPYTNGQKQE FNNQATNVIKFSDPQWNHFQGPSCQGLEPYNKVTYKPYQSSAQNNGSPAQEITGSDTF EGLQQQFLGANENSAENMQIIQLQVLNKAKERQLENLIEKLNESERQIRYLNHQLVII KDEKDGLTLSLRESQKLFQNGKEREIQLEAQIKALETQIQALKVNEEQMIKKSRTTEM ALESLKQQLVDLHHSESLQRAREQHESIVMGLTKKYEEQVLSLQKNLDATVTALKEQE DICSRLKDHVKQLERNQEAIKLEKTEIINKLTRSLEESQKQCAHLLQSGSVQEVAQLQ FQLQQAQKAHAMSANMNKALQEELTELKDEISLYESAAKLGIHPSDSEGELNIELTES YVDLGIKKVNWKKSKVTSIVQEEDPNEELSKDEFILKLKAEVQRLLGSNSMKRHLVSQ LQNDLKDCHKKIEDLHQVKKDEKSIEVETKTDTSEKPKNQLWPESSTSDVVRDDILLL KNEIQVLQQQNQELKETEGKLRNTNQDLCNQMRQMVQDFDHDKQEAVDRCERTYQQHH EAMKTQIRESLLAKHALEKQQLFEAYERTHLQLRSELDKLNKEVTAVQECYLEVCREK DNLELTLRKTTEKEQQTQEKIKEKLIQQLEKEWQSKLDQTIKAMKKKTLDCGSQTDQV TTSDVISKKEMAIMIEEQKCTIQQNLEQEKDIAIKGAMKKLEIELELKHCENITKQVE IAVQNAHQRWLGELPELAEYQALVKAEQKKWEEQHEVSVNKRISFAVSEAKEKWKSEL ENMRKNILPGKELEEKIHSLQKELELKNEEVPVVIRAELAKARSEWNKEKQEEIHRIQ EQNEQDYRQFLDDHRNKINEVLAAAKEDFMKQKTELLLQKETELQTCLDQSRREWTMQ EAKRIQLEIYQYEEDILTVLGVLLSDTQKEHISDSEDKQLLEIMSTCSSKWMSVQYFE KLKGCIQKAFQDTLPLLVENADPEWKKRNMAELSKDSASQGTGQGDPGPAAGHHAQPL ALQATEAEAEENNKVVEELIEENNDMKNKLEELQTLCKTPPRSLSAGAIENACLPCSG GALEELRGQYIKAVKKIKCDMLRYIQESKERAAEMVKAEVLRERQETARKMRKYYLIC LQQILQDDGKEGAEKKIMNAASKLATMAKLLETPISSKSQSKTTQSALPLTSEMLIAV KKSKRNDVNQKIPCCIESKSNSVNTITRTLCEQAPKRRAACNLQRLLENSEHQSIKHV GSKETHLEFQFGDGSCKHLNSLPRNVSPEFVPCEGEGGFGLHKKKDLLSDNGSESLPH SAAYPFLGTLGNKPSPRCTPGPSESGCMHITFRDSNERLGLKVYKCNPLMESENAASE KSQGLDVQEPPVKDGGDLSDCLGWPSSSATLSFDSREASFVHGRPQGTLEIPSESVKS KQFSPSGYLSDTEESNMICQTMKCQRYQTPYLSEETTYLEPGKISVNCGHPSRHKADR LKSDFKKLSSTLPSSVCQQPSRKLIVPLSSQQDSGFDSPFVNLD (SEQ ID NO: 12) CFL1 1072 NM_005507 Homo sapiens cofilin 1 (non-muscle) (CFL1), mRNA mRNA Sequence GGCCGGCGGGAAGACTCCGTTACCCAGCGAGCGAGGCGGCGGCGCAGGGCCAGCGGACTCCATTTCCCGT CGGCTCGCGGTGGGAGCGCCGGAAGCCCGCCCCACCCCTCATTGTGCGGCTCCTACTAAACGGAAGGGGC CGGGAGAGGCCGCGTTCAGTCGGGTCCCGGCAGCGGCTGCAGCGCTCTCGTCTTCTGCGGCTCTCGGTGC CCTCTCCTTTTCGTTTCCGGAAACATGGCCTCCGGTGTGGCTGTCTCTGATGGTGTCATCAAGGTGTTCA ACGACATGAAGGTGCGTAAGTCTTCAACGCCAGAGGAGGTGAAGAAGCGCAAGAAGGCGGTGCTCTTCTG CCTGAGTGAGGACAAGAAGAACATCATCCTGGAGGAGGGCAAGGAGATCCTGGTGGGCGATGTGGGCCAG ACTGTCGACGACCCCTACGCCACCTTTGTCAAGATGCTGCCAGATAAGGACTGCCGCTATGCCCTCTATG ATGCAACCTATGAGACCAAGGAGAGCAAGAAGGAGGATCTGGTGTTTATCTTCTGGGCCCCCGAGTCTGC GCCCCTTAAGAGCAAAATGATTTATGCCAGCTCCAAGGACGCCATCAAGAAGAAGCTGACAGGGATCAAG CATGAATTGCAAGCAAACTGCTACGAGGAGGTCAAGGACCGCTGCACCCTGGCAGAGAAGCTGGGGGGCA GTGCCGTCATCTCCCTGGAGGGCAAGCCTTTGTGAGCCCCTTCTGGCCCCCTGCCTGGAGCATCTGGCAG CCCCACACCTGCCCTTGGGGGTTGCAGGCTGCCCCCTTCCTGCCAGACCGGAGGGGCTGGGGGGATCCCA GCAGGGGGAGGGCAATCCCTTCACCCCAGTTGCCAAACAGACCCCCCACCCCCTGGATTTTCCTTCTCCC TCCATCCCTTGACGGTTCTGGCCTTCCCAAACTGCTTTTGATCTTTTGATTCCTCTTGGGCTGAAGCAGA CCAAGTTCCCCCCAGGCACCCCAGTTGTGGGGGAGCCTGTATTTTTTTTAACAACATCCCCATTCCCCAC CTGGTCCTCCCCCTTCCCATGCTGCCAACTTCTAACCGCAATAGTGACTCTGTGCTTGTCTGTTTAGTTC TGTGTATAAATGGAATGTTGTGGAGATGACCCCTCCCTGTGCCGGCTGGTTCCTCTCCCTTTTCCCCTGG TCACGGCTACTCATGGAAGCAGGACCAGTAAGGGACCTTCGATTAAAAAAAAAAAAGACAATAATAAAAA (SEQ ID NO: 13) Translated protein sequence MASGVAVSDGVIKVFNDMKVRKSSTPEEVKKRKKAVLFCLSEDK KNIILEEGKEILVGDVGQTVDDPYATFVKMLPDKDCRYALYDATYETKESKKEDLVFI FWAPESAPLKSKMIYASSKDAIKKKLTGIKHELQANCYEEVKDRCTLAEKLGGSAVIS LEGKPL (SEQ ID NO: 14) CKLF 51192 NM_016326 Homo sapiens chemokine-like factor (CKLF), transcript variant 3, mRNA mRNA Sequence ATGCGCGCAAGAGAGCGGGAAGCCGAGCTGGGCGAGAAGTAGGGGAGGGCGGTGCTCCGCCGCGGTGGCG GTTGCTATCGCTTCGCAGAACCTACTCAGGCAGCCAGCTGAGAAGAGTTGAGGGAAAGTGCTGCTGCTGG GTCTGCAGACGCGATGGATAACGTGCAGCCGAAAATAAAACATCGCCCCTTCTGCTTCAGTGTGAAAGGC CACGTGAAGATGCTGCGGCTGGTGTTTGCACTTGTGACAGCAGTATGCTGTCTTGCCGACGGGGCCCTTA TTTACCGGAAGCTTCTGTTCAATCCCAGCGGTCCTTACCAGAAAAAGCCTGTGCATGAAAAAAAAGAAGT TTTGTAATTTTATATTACTTTTTAGTTTGATACTAAGTATTAAACATATTTCTGTATTCTTCCACATATT TTCTGCAGTTATTTTAACTCAGTATAGGAGCTAGAGGAAGAGATTTCCGAAGTCTGCACCCCGCGCAGAG CACTACTGTAACTTCCAAGGGAGCGCTGGGAGCAGCGGGATCGGGTTTTCCGGCACCCGGGCCTGGGTGG CAGGGAAGAATGTGCCGGGATCCGCCTCAGGGATCTTTGAATCTCTTTACTGCCTGGCTGGCCGGCAGCT CCG (SEQ ID NO: 15) Translated protein sequence MDNVQPKIKHRPFCFSVKGHVKMLRLVFALVTAVCCLADGALIY RKLLFNPSGPYQKKPVHEKKEVL (SEQ ID NO: 16) COL7A1 1294 NM_000094 Homo sapiens collagen, type VII, alpha 1 (COL7A1), mRNA mRNA Sequence GATGACGCTGCGGCTTCTGGTGGCCGCGCTCTGCGCCGGGATCCTGGCAGAGGCGCCCCGAGTGCGAGCC CAGCACAGGGAGAGAGTGACCTGCACGCGCCTTTACGCCGCTGACATTGTGTTCTTACTGGATGGCTCCT CATCCATTGGCCGCAGCAATTTCCGCGAGGTCCGCAGCTTTCTCGAAGGGCTGGTGCTGCCTTTCTCTGG AGCAGCCAGTGCACAGGGTGTGCGCTTTGCCACAGTGCAGTACAGCGATGACCCACGGACAGAGTTCGGC CTGGATGCACTTGGCTCTGGGGGTGATGTGATCCGCGCCATCCGTGAGCTTAGCTACAAGGGGGGCAACA CTCGCACAGGGGCTGCAATTCTCCATGTGGCTGACCATGTCTTCCTGCCCCAGCTGGCCCGACCTGGTGT CCCCAAGGTCTGCATCCTGATCACAGACGGGAAGTCCCAGGACCTGGTGGACACAGCTGCCCAAAGGCTG AAGGGGCAGGGGGTCAAGCTATTTGCTGTGGGGATCAAGAATGCTGACCCTGAGGAGCTGAAGCGAGTTG CCTCACAGCCCACCAGTGACTTCTTCTTCTTCGTCAATGACTTCAGCATCTTGAGGACACTACTGCCCCT CGTTTCCCGGAGAGTGTGCACGACTGCTGGTGGCGTGCCTGTGACCCGACCTCCGGATGACTCGACCTCT GCTCCACGAGACCTGGTGCTGTCTGAGCCAAGCAGCCAATCCTTGAGAGTACAGTGGACAGCGGCCAGTG GCCCTGTGACTGGCTACAAGGTCCAGTACACTCCTCTGACGGGGCTGGGACAGCCACTGCCGAGTGAGCG GCAGGAGGTGAACGTCCCAGCTGGTGAGACCAGTGTGCGGCTGCGGGGTCTCCGGCCACTGACCGAGTAC CAAGTGACTGTGATTGCCCTCTACGCCAACAGCATCGGGGAGGCTGTGAGCGGGACAGCTCGGACCACTG CCCTAGAAGGGCCGGAACTGACCATCCAGAATACCACAGCCCACAGCCTCCTGGTGGCCTGGCGGAGTGT GCCAGGTGCCACTGGCTACCGTGTGACATGGCGGGTCCTCAGTGGTGGGCCCACACAGCAGCAGGAGCTG GGCCCTGGGCAGGGTTCAGTGTTGCTGCGTGACTTGGAGCCTGGCACGGACTATGAGGTGACCGTGAGCA CCCTATTTGGCCGCAGTGTGGGGCCCGCCACTTCCCTGATGGCTCGCACTGACGCTTCTGTTGAGCAGAC CCTGCGCCCGGTCATCCTGGGCCCCACATCCATCCTCCTTTCCTGGAACTTGGTGCCTGAGGCCCGTGGC TACCGGTTGGAATGGCGGCGTGAGACTGGCTTGGAGCCACCGCAGAAGGTGGTACTGCCCTCTGATGTGA CCCGCTACCAGTTGGATGGGCTGCAGCCGGGCACTGAGTACCGCCTCACACTCTACACTCTGCTGGAGGG CCACGAGGTGGCCACCCCTGCAACCGTGGTTCCCACTGGACCAGAGCTGCCTGTGAGCCCTGTAACAGAC CTGCAAGCCACCGAGCTGCCCGGGCAGCGGGTGCGAGTGTCCTGGAGCCCAGTCCCTGGTGCCACCCAGT ACCGCATCATTGTGCGCAGCACCCAGGGGGTTGAGCGGACCCTGGTGCTTCCTGGGAGTCAGACAGCATT CGACTTGGATGACGTTCAGGCTGGGCTTAGCTACACTGTGCGGGTGTCTGCTCGAGTGGGTCCCCGTGAG GGCAGTGCCAGTGTCCTCACTGTCCGCCGGGAGCCGGAAACTCCACTTGCTGTTCCAGGGCTGCGGGTTG TGGTGTCAGATGCAACGCGAGTGAGGGTGGCCTGGGGACCCGTCCCTGGAGCCAGTGGATTTCGGATTAG CTGGAGCACAGGCAGTGGTCCGGAGTCCAGCCAGACACTGCCCCCAGACTCTACTGCCACAGACATCACA GGGCTGCAGCCTGGAACCACCTACCAGGTGGCTGTGTCGGTACTGCGAGGCAGAGAGGAGGGCCCTGCTG CAGTCATCGTGGCTCGAACGGACCCACTGGGCCCAGTGAGGACGGTCCATGTGACTCAGGCCAGCAGCTC ATCTGTCACCATTACCTGGACCAGGGTTCCTGGCGCCACAGGATACAGGGTTTCCTGGCACTCAGCCCAC GGCCCAGAGAAATCCCAGTTGGTTTCTGGGGAGGCCACGGTGGCTGAGCTGGATGGACTGGAGCCAGATA CTGAGTATACGGTGCATGTGAGGGCCCATGTGGCTGGCGTGGATGGGCCCCCTGCCTCTGTGGTTGTGAG GACTGCCCCTGAGCCTGTGGGTCGTGTGTCGAGGCTGCAGATCCTCAATGCTTCCAGCGACGTTCTACGG ATCACCTGGGTAGGGGTCACTGGAGCCACAGCTTACAGACTGGCCTGGGGCCGGAGTGAAGGCGGCCCCA TGAGGCACCAGATACTCCCAGGAAACACAGACTCTGCAGAGATCCGGGGTCTCGAAGGTGGAGTCAGCTA CTCAGTGCGAGTGACTGCACTTGTCGGGGACCGCGAGGGCACACCTGTCTCCATTGTTGTCACTACGCCG CCTGAGGCTCCGCCAGCCCTGGGGACGCTTCACGTGGTGCAGCGCGGGGAGCACTCGCTGAGGCTGCGCT GGGAGCCGGTGCCCAGAGCGCAGGGCTTCCTTCTGCACTGGCAACCTGAGGGTGGCCAGGAACAGTCCCG GGTCCTGGGGCCCGAGCTCAGCAGCTATCACCTGGACGGGCTGGAGCCAGCGACACAGTACCGCGTGAGG CTGAGTGTCCTAGGGCCAGCTGGAGAAGGGCCCTCTGCAGAGGTGACTGCGCGCACTGAGTCACCTCGTG TTCCAAGCATTGAACTACGTGTGGTGGACACCTCGATCGACTCGGTGACTTTGGCCTGGACTCCAGTGTC CAGGGCATCCAGCTACATCCTATCCTGGCGGCCACTCAGAGGCCCTGGCCAGGAAGTGCCTGGGTCCCCG CAGACACTTCCAGGGATCTCAAGCTCCCAGCGGGTGACAGGGCTAGAGCCTGGCGTCTCTTACATCTTCT CCCTGACGCCTGTCCTGGATGGTGTGCGGGGTCCTGAGGCATCTGTCACACAGACGCCAGTGTGCCCCCG TGGCCTGGCGGATGTGGTGTTCCTACCACATGCCACTCAAGACAATGCTCACCGTGCGGAGGCTACGAGG AGGGTCCTGGAGCGTCTGGTGTTGGCACTTGGGCCTCTTGGGCCACAGGCAGTTCAGGTTGGCCTGCTGT CTTACAGTCATCGGCCCTCCCCACTGTTCCCACTGAATGGCTCCCATGACCTTGGCATTATCTTGCAAAG GATCCGTGACATGCCCTACATGGACCCAAGTGGGAACAACCTGGGCACAGCCGTGGTCACAGCTCACAGA TACATGTTGGCACCAGATGCTCCTGGGCGCCGCCAGCACGTACCAGGGGTGATGGTTCTGCTAGTGGATG AACCCTTGAGAGGTGACATATTCAGCCCCATCCGTGAGGCCCAGGCTTCTGGGCTTAATGTGGTGATGTT GGGAATGGCTGGAGCGGACCCAGAGCAGCTGCGTCGCTTGGCGCCGGGTATGGACTCTGTCCAGACCTTC TTCGCCGTGGATGATGGGCCAAGCCTGGACCAGGCAGTCAGTGGTCTGGCCACAGCCCTGTGTCAGGCAT CCTTCACTACTCAGCCCCGGCCAGAGCCCTGCCCAGTGTATTGTCCAAAGGGCCAGAAGGGGGAACCTGG AGAGATGGGCCTGAGAGGACAAGTTGGGCCTCCTGGCGACCCTGGCCTCCCGGGCAGGACCGGTGCTCCC GGCCCCCAGGGGCCCCCTGGAAGTGCCACTGCCAAGGGCGAGAGGGGCTTCCCTGGAGCAGATGGGCGTC CAGGCAGCCCTGGCCGCGCCGGGAATCCTGGGACCCCTGGAGCCCCTGGCCTAAAGGGCTCTCCAGGGTT GCCTGGCCCTCGTGGGGACCCGGGAGAGCGAGGACCTCGAGGCCCAAAGGGGGAGCCGGGGGCTCCCGGA CAAGTCATCGGAGGTGAAGGACCTGGGCTTCCTGGGCGGAAAGGGGACCCTGGACCATCGGGCCCCCCTG GACCTCGTGGACCACTGGGGGACCCAGGACCCCGTGGCCCCCCAGGGCTTCCTGGAACAGCCATGAAGGG TGACAAAGGCGATCGTGGGGAGCGGGGTCCCCCTGGACCAGGTGAAGGTGGCATTGCTCCTGGGGAGCCT GGGCTGCCGGGTCTTCCCGGAAGCCCTGGACCCCAAGGCCCCGTTGGCCCCCCTGGAAAGAAAGGAGAAA AAGGTGACTCTGAGGATGGAGCTCCAGGCCTCCCAGGACAACCTGGGTCTCCGGGTGAGCAGGGCCCACG GGGACCTCCTGGAGCTATTGGCCCCAAAGGTGACCGGGGCTTTCCAGGGCCCCTGGGTGAGGCTGGAGAG AAGGGCGAACGTGGACCCCCAGGCCCAGCGGGATCCCGGGGGCTGCCAGGGGTTGCTGGACGTCCTGGAG CCAAGGGTCCTGAAGGGCCACCAGGACCCACTGGCCGCCAAGGAGAGAAGGGGGAGCCTGGTCGCCCTGG GGACCCTGCAGTGGTGGGACCTGCTGTTGCTGGACCCAAAGGAGAAAAGGGAGATGTGGGGCCCGCTGGG CCCAGAGGAGCTACCGGAGTCCAAGGGGAACGGGGCCCACCCGGCTTGGTTCTTCCTGGAGACCCTGGCC CCAAGGGAGACCCTGGAGACCGGGGTCCCATTGGCCTTACTGGCAGAGCAGGACCCCCAGGTGACTCAGG GCCTCCTGGAGAGAAGGGAGACCCTGGGCGGCCTGGCCCCCCAGGACCTGTTGGCCCCCGAGGACGAGAT GGTGAAGTTGGAGAGAAAGGTGACGAGGGTCCTCCGGGTGACCCGGGTTTGCCTGGAAAAGCAGGCGAGC GTGGCCTTCGGGGGGCACCTGGAGTTCGGGGGCCTGTGGGTGAAAAGGGAGACCAGGGAGATCCTGGAGA GGATGGACGAAATGGCAGCCCTGGATCATCTGGACCCAAGGGTGACCGTGGGGAGCCGGGTCCCCCAGGA CCCCCGGGACGGCTGGTAGACACAGGACCTGGAGCCAGAGAGAAGGGAGAGCCTGGGGACCGCGGACAAG AGGGTCCTCGAGGGCCCAAGGGTGATCCTGGCCTCCCTGGAGCCCCTGGGGAAAGGGGCATTGAAGGGTT TCGGGGACCCCCAGGCCCACAGGGGGACCCAGGTGTCCGAGGCCCAGCAGGAGAAAAGGGTGACCGGGGT CCCCCTGGGCTGGATGGCCGGAGCGGACTGGATGGGAAACCAGGAGCCGCTGGGCCCTCTGGGCCGAATG GTGCTGCAGGCAAAGCTGGGGACCCAGGGAGAGACGGGCTTCCAGGCCTCCGTGGAGAACAGGGCCTCCC TGGCCCCTCTGGTCCCCCTGGATTACCGGGAAAGCCAGGCGAGGATGGCAAACCTGGCCTGAATGGAAAA AACGGAGAACCTGGGGACCCTGGAGAAGACGGGAGGAAGGGAGAGAAAGGAGATTCAGGCGCCTCTGGGA GAGAAGGTCGTGATGGCCCCAAGGGTGAGCGTGGAGCTCCTGGTATCCTTGGACCCCAGGGGCCTCCAGG CCTCCCAGGGCCAGTGGGCCCTCCTGGCCAGGGTTTTCCTGGTGTCCCAGGAGGCACGGGCCCCAAGGGT GACCGTGGGGAGACTGGATCCAAAGGGGAGCAGGGCCTCCCTGGAGAGCGTGGCCTGCGAGGAGAGCCTG GAAGTGTGCCGAATGTGGATCGGTTGCTGGAAACTGCTGGCATCAAGGCATCTGCCCTGCGGGAGATCGT GGAGACCTGGGATGAGAGCTCTGGTAGCTTCCTGCCTGTGCCCGAACGGCGTCGAGGCCCCAAGGGGGAC TCAGGCGAACAGGGCCCCCCAGGCAAGGAGGGCCCCATCGGCTTTCCTGGAGAACGCGGGCTGAAGGGCG ACCGTGGAGACCCTGGCCCTCAGGGGCCACCTGGTCTGGCCCTTGGGGAGAGGGGCCCCCCCGGGCCTTC CGGCCTTGCCGGGGAGCCTGGAAAGCCTGGTATTCCCGGGCTCCCAGGCAGGGCTGGGGGTGTGGGAGAG GCAGGAAGGCCAGGAGAGAGGGGAGAACGGGGAGAGAAAGGAGAACGTGGAGAACAGGGCAGAGATGGCC CTCCTGGACTCCCTGGAACCCCTGGGCCCCCCGGACCCCCTGGCCCCAAGGTGTCTGTGGATGAGCCAGG TCCTGGACTCTCTGGAGAACAGGGACCCCCTGGACTCAAGGGTGCTAAGGGGGAGCCGGGCAGCAATGGT GACCAAGGTCCCAAAGGAGACAGGGGTGTGCCAGGCATCAAAGGAGACCGGGGAGAGCCTGGACCGAGGG GTCAGGACGGCAACCCGGGTCTACCAGGAGAGCGTGGTATGGCTGGGCCTGAAGGGAAGCCGGGTCTGCA GGGTCCAAGAGGCCCCCCTGGCCCAGTGGGTGGTCATGGAGACCCTGGACCACCTGGTGCCCCGGGTCTT GCTGGCCCTGCAGGACCCCAAGGACCTTCTGGCCTGAAGGGGGAGCCTGGAGAGACAGGACCTCCAGGAC GGGGCCTGACTGGACCTACTGGAGCTGTGGGACTTCCTGGACCCCCCGGCCCTTCAGGCCTTGTGGGTCC ACAGGGGTCTCCAGGTTTGCCTGGACAAGTGGGGGAGACAGGGAAGCCGGGAGCCCCAGGTCGAGATGGT GCCAGTGGAAAAGATGGAGACAGAGGGAGCCCTGGTGTGCCAGGGTCACCAGGTCTGCCTGGCCCTGTCG GACCTAAAGGAGAACCTGGCCCCACGGGGGCCCCTGGACAGGCTGTGGTCGGGCTCCCTGGAGCAAAGGG AGAGAAGGGAGCCCCTGGAGGCCTTGCTGGAGACCTGGTGGGTGAGCCGGGAGCCAAAGGTGACCGAGGA CTGCCAGGGCCGCGAGGCGAGAAGGGTGAAGCTGGCCGTGCAGGGGAGCCCGGAGACCCTGGGGAAGATG GTCAGAAAGGGGCTCCAGGACCCAAAGGTTTCAAGGGTGACCCAGGAGTCGGGGTCCCGGGCTCCCCTGG GCCTCCTGGCCCTCCAGGTGTGAAGGGAGATCTGGGCCTCCCTGGCCTGCCCGGTGCTCCTGGTGTTGTT GGGTTCCCGGGTCAGACAGGCCCTCGAGGAGAGATGGGTCAGCCAGGCCCTAGTGGAGAGCGGGGTCTGG CAGGCCCCCCAGGGAGAGAAGGAATCCCAGGACCCCTGGGGCCACCTGGACCACCGGGGTCAGTGGGACC ACCTGGGGCCTCTGGACTCAAAGGAGACAAGGGAGACCCTGGAGTAGGGCTGCCTGGGCCCCGAGGCGAG CGTGGGGAGCCAGGCATCCGGGGTGAAGATGGCCGCCCCGGCCAGGAGGGACCCCGAGGACTCACGGGGC CCCCTGGCAGCAGGGGAGAGCGTGGGGAGAAGGGTGATGTTGGGAGTGCAGGACTAAAGGGTGACAAGGG AGACTCAGCTGTGATCCTGGGGCCTCCAGGCCCACGGGGTGCCAAGGGGGACATGGGTGAACGAGGGCCT CGGGGCTTGGATGGTGACAAAGGACCTCGGGGAGACAATGGGGACCCTGGTGACAAGGGCAGCAAGGGAG AGCCTGGTGACAAGGGCTCAGCCGGGTTGCCAGGACTGCGTGGACTCCTGGGACCCCAGGGTCAACCTGG TGCAGCAGGGATCCCTGGTGACCCGGGATCCCCAGGAAAGGATGGAGTGCCTGGTATCCGAGGAGAAAAA GGAGATGTTGGCTTCATGGGTCCCCGGGGCCTCAAGGGTGAACGGGGAGTGAAGGGAGCCTGTGGCCTTG ATGGAGAGAAGGGAGACAAGGGAGAAGCTGGTCCCCCAGGCCGCCCCGGGCTGGCAGGACACAAAGGAGA GATGGGGGAGCCTGGTGTGCCGGGCCAGTCGGGGGCCCCTGGCAAGGAGGGCCTGATCGGTCCCAAGGGT GACCGAGGCTTTGACGGGCAGCCAGGCCCCAAGGGTGACCAGGGCGAGAAAGGGGAGCGGGGAACCCCAG GAATTGGGGGCTTCCCAGGCCCCAGTGGAAATGATGGCTCTGCTGGTCCCCCAGGGCCACCTGGCAGTGT TGGTCCCAGAGGCCCCGAAGGACTTCAGGGCCAGAAGGGTGAGCGAGGTCCCCCCGGAGAGAGAGTGGTG GGGGCTCCTGGGGTCCCTGGAGCTCCTGGCGAGAGAGGGGAGCAGGGGCGGCCAGGGCCTGCCGGTCCTC GAGGCGAGAAGGGAGAAGCTGCACTGACGGAGGATGACATCCGGGGCTTTGTGCGCCAAGAGATGAGTCA GCACTGTGCCTGCCAGGGCCAGTTCATCGCATCTGGATCACGACCCCTCCCTAGTTATGCTGCAGACACT GCCGGCTCCCAGCTCCATGCTGTGCCTGTGCTCCGCGTCTCTCATGCAGAGGAGGAAGAGCGGGTACCCC CTGAGGATGATGAGTACTCTGAATACTCCGAGTATTCTGTGGAGGAGTACCAGGACCCTGAAGCTCCTTG GGATAGTGATGACCCCTGTTCCCTGCCACTGGATGAGGGCTCCTGCACTGCCTACACCCTGCGCTGGTAC CATCGGGCTGTGACAGGCAGCACAGAGGCCTGTCACCCTTTTGTCTATGGTGGCTGTGGAGGGAATGCCA ACCGTTTTGGGACCCGTGAGGCCTGCGAGCGCCGCTGCCCACCCCGGGTGGTCCAGAGCCAGGGGACAGG TACTGCCCAGGACTGAGGCCCAGATAATGAGCTGAGATTCAGCATCCCCTGGAGGAGTCGGGGTCTCAGC AGAACCCCACTGTCCCTCCCCTTGGTGCTAGAGGCTTGTGTGCACGTGAGCGTGCGTGTGCACGTCCGTT ATTTCAGTGACTTGGTCCCGTGGGTCTAGCCTTCCCCCCTGTGGACAAACCCCCATTGTGGCTCCTGCCA CCCTGGCAGATGACTCACTGTGGGGGGGTGGCTGTGGGCAGTGAGCGGATGTGACTGGCGTCTGACCCGC CCCTTGACCCAAGCCTGTGATGACATGGTGCTGATTCTGGGGGGCATTAAAGCTGCTGTTTTAAAAGGC (SEQ ID NO: 17) Translated protein sequence MTLRLLVAALCAGILAEAPRVRAQHRERVTCTRLYAADIVFLLD GSSSIGRSNFREVRSFLEGLVLPFSGAASAQGVRFATVQYSDDPRTEFGLDALGSGGD VIRAIRELSYKGGNTRTGAAILHVADHVFLPQLARPGVPKVCILITDGKSQDLVDTAA QRLKGQGVKLFAVGIKNADPEELKRVASQPTSDFFFFVNDFSILRTLLPLVSRRVCTT AGGVPVTRPPDDSTSAPRDLVLSEPSSQSLRVQWTAASGPVTGYKVQYTPLTGLGQPL PSERQEVNVPAGETSVRLRGLRPLTEYQVTVIALYANSIGEAVSGTARTTALEGPELT IQNTTAHSLLVAWRSVPGATGYRVTWRVLSGGPTQQQELGPGQGSVLLRDLEPGTDYE VTVSTLFGRSVGPATSLMARTDASVEQTLRPVILGPTSILLSWNLVPEARGYRLEWRR ETGLEPPQKVVLPSDVTRYQLDGLQPGTEYRLTLYTLLEGHEVATPATVVPTGPELPV SPVTDLQATELPGQRVRVSWSPVPGATQYRIIVRSTQGVERTLVLPGSQTAFDLDDVQ AGLSYTVRVSARVGPREGSASVLTVRREPETPLAVPGLRVVVSDATRVRVAWGPVPGA SGFRISWSTGSGPESSQTLPPDSTATDITGLQPGTTYQVAVSVLRGREEGPAAVIVAR TDPLGPVRTVHVTQASSSSVTITWTRVPGATGYRVSWHSAHGPEKSQLVSGEATVAEL DGLEPDTEYTVHVRAHVAGVDGPPASVVVRTAPEPVGRVSRLQILNASSDVLRITWVG VTGATAYRLAWGRSEGGPMRHQILPGNTDSAEIRGLEGGVSYSVRVTALVGDREGTPV SIVVTTPPEAPPALGTLHVVQRGEHSLRLRWEPVPRAQGFLLHWQPEGGQEQSRVLGP ELSSYHLDGLEPATQYRVRLSVLGPAGEGPSAEVTARTESPRVPSIELRVVDTSIDSV TLAWTPVSRASSYILSWRPLRGPGQEVPGSPQTLPGISSSQRVTGLEPGVSYIFSLTP VLDGVRGPEASVTQTPVCPRGLADVVFLPHATQDNAHRAEATRRVLERLVLALGPLGP QAVQVGLLSYSHRPSPLFPLNGSHDLGTTLQRIRDMPYMDPSGNNLGTAVVTAHRYML APDAPGRRQHVPGVMVLLVDEPLRGDIFSPIREAQASGLNVVMLGMAGADPEQLRRLA PGMDSVQTFFAVDDGPSLDQAVSGLATALCQASFTTQPRPEPCPVYCPKGQKGEPGEM GLRGQVGPPGDPGLPGRTGAPGPQGPPGSATAKGERGFPGADGRPGSPGRAGNPGTPG APGLKGSPGLPGPRGDPGERGPRGPKGEPGAPGQVIGGEGPGLPGRKGDPGPSGPPGP RGPLGDPGPRGPPGLPGTAMKGDKGDRGERGPPGPGEGGIAPGEPGLPGLPGSPGPQG PVGPPGKKGEKGDSEDGAPGLPGQPGSPGEQGPRGPPGAIGPKGDRGFPGPLGEAGEK GERGPPGPAGSRGLPGVAGRPGAKGPEGPPGPTGRQGEKGEPGRPGDPAVVGPAVAGP KGEKGDVGPAGPRGATGVQGERGPPGLVLPGDPGPKGDPGDRGPIGLTGRAGPPGDSG PPGEKGDPGRPGPPGPVGPRGRDGEVGEKGDEGPPGDPGLPGKAGERGLRGAPGVRGP VGEKGDQGDPGEDGRNGSPGSSGPKGDRGEPGPPGPPGRLVDTGPGAREKGEPGDRGQ EGPRGPKGDPGLPGAPGERGIEGFRGPPGPQGDPGVRGPAGEKGDRGPPGLDGRSGLD GKPGAAGPSGPNGAAGKAGDPGRDGLPGLRGEQGLPGPSGPPGLPGKPGEDGKPGLNG KNGEPGDPGEDGRKGEKGDSGASGREGRDGPKGERGAPGILGPQGPPGLPGPVGPPGQ GFPGVPGGTGPKGDRGETGSKGEQGLPGERGLRGEPGSVPNVDRLLETAGIKASALRE IVETWDESSGSFLPVPERRRGPKGDSGEQGPPGKEGPIGFPGERGLKGDRGDPGPQGP PGLALGERGPPGPSGLAGEPGKPGIPGLPGRAGGVGEAGRPGERGERGEKGERGEQGR DGPPGLPGTPGPPGPPGPKVSVDEPGPGLSGEQGPPGLKGAKGEPGSNGDQGPKGDRG VPGIKGDRGEPGPRGQDGNPGLPGERGMAGPEGKPGLQGPRGPPGPVGGHGDPGPPGA PGLAGPAGPQGPSGLKGEPGETGPPGRGLTGPTGAVGLPGPPGPSGLVGPQGSPGLPG QVGETGKPGAPGRDGASGKDGDRGSPGVPGSPGLPGPVGPKGEPGPTGAPGQAVVGLP GAKGEKGAPGGLAGDLVGEPGAKGDRGLPGPRGEKGEAGRAGEPGDPGEDGQKGAPGP KGFKGDPGVGVPGSPGPPGPPGVKGDLGLPGLPGAPGVVGFPGQTGPRGEMGQPGPSG ERGLAGPPGREGIPGPLGPPGPPGSVGPPGASGLKGDKGDPGVGLPGPRGERGEPGIR GEDGRPGQEGPRGLTGPPGSRGERGEKGDVGSAGLKGDKGDSAVILGPPGPRGAKGDM GERGPRGLDGDKGPRGDNGDPGDKGSKGEPGDKGSAGLPGLRGLLGPQGQPGAAGIPG DPGSPGKDGVPGIRGEKGDVGFMGPRGLKGERGVKGACGLDGEKGDKGEAGPPGRPGL AGHKGEMGEPGVPGQSGAPGKEGLIGPKGDRGFDGQPGPKGDQGEKGERGTPGIGGFP GPSGNDGSAGPPGPPGSVGPRGPEGLQGQKGERGPPGERVVGAPGVPGAPGERGEQGR PGPAGPRGEKGEAALTEDDIRGFVRQEMSQHCACQGQFIASGSRPLPSYAADTAGSQL HAVPVLRVSHAEEEERVPPEDDEYSEYSEYSVEEYQDPEAPWDSDDPCSLPLDEGSCT AYTLRWYHRAVTGSTEACHPFVYGGCGGNANRFGTREACERRCPPRVVQSQGTGTAQD (SEQ ID NO: 18) CYP4F3 4051 NM_000896 Homo sapiens cytochrome P450, family 4, subfamily F, polypeptide 3 (CYP4F3), mRNA mRNA Sequence AGAAGAAGGGGAGAGGAGGTTGTGTGGGACAAGGTGCTCCTGACAGAAGGATGCCACAGCTGAGCCTGTC CTCGCTGGGCCTTTGGCCAATGGCAGCATCCCCGTGGCTGCTCCTGCTGCTGGTTGGGGCCTCCTGGCTC CTGGCCCGCATCCTGGCCTGGACCTATACCTTCTATGACAACTGCTGCCGCCTCCGGTGTTTCCCGCAAC CCCCGAAACGGAATTGGTTCTTGGGTCACCTGGGCCTGATTCACAGCTCGGAGGAAGGTCTCCTATACAC ACAAAGCCTGGCATGCACCTTCGGTGATATGTGCTGCTGGTGGGTGGGGCCCTGGCACGCAATCGTCCGC ATCTTCCACCCCACCTACATCAAGCCTGTGCTCTTTGCTCCAGCTGCCATTGTACCAAAGGACAAGGTCT TCTACAGCTTCCTGAAGCCCTGGCTGGGGGATGGGCTCCTGCTGAGTGCTGGTGAAAAGTGGAGCCGCCA CCGTCGGATGCTGACGCCTGCCTTCCATTTCAACATCCTGAAGCCCTATATGAAGATTTTCAATGAGAGT GTGAACATCATGCATGCCAAGTGGCAGCTCCTGGCCTCAGAGGGTAGTGCCCGTCTGGACATGTTTGAGC ACATCAGCCTCATGACCTTGGACAGTCTGCAGAAATGTGTCTTCAGCTTTGACAGCCATTGCCAGGAGAA GCCCAGTGAATATATTGCCGCCATCTTGGAGCTCAGTGCCCTTGTGACAAAAAGACACCAGCAGATCCTC CTGTACATAGACTTCCTGTATTATCTCACCCCTGATGGGCAGCGTTTCCGCAGGGCCTGCCGCCTGGTGC ACGACTTCACAGATGCCGTCATCCAGGAGCGGCGCCGCACCCTCCCTAGCCAGGGTGTTGATGACTTCCT CCAAGCCAAGGCCAAATCCAAGACTTTGGACTTCATTGATGTACTCCTGCTGAGCAAGGATGAAGATGGG AAGAAGTTGTCCGATGAGGACATAAGAGCAGAAGCTGACACCTTTATGTTTGAGGGCCATGACACCACAG CCAGTGGTCTCTCCTGGGTCCTGTACCACCTTGCAAAGCACCCGGAATACCAGGAGCGCTGTCGGCAGGA GGTGCAAGAGCTTCTGAAGGACCGTGAGCCTAAAGAGATTGAATGGGACGACCTGGCCCAGCTGCCCTTC CTGACCATGTGCATTAAGGAGAGCCTGAGGCTGCATCCCCCAGTCCCTGCCGTCTCTCGCTGCTGCACCC AAGACATTGTGCTCCCAGACGGCCGGGTCATCCCCAAAGGCATTATCTGCCTCATCAGTGTTTTTGGAAC CCATCACAACCCAGCCGTGTGGCCGGACCCTGAGGTCTATGACCCCTTTCGCTTTGACCCAAAGAACATC AAGGAGAGGTCACCTCTGGCTTTTATTCCCTTCTCAGCAGGGCCCAGGAACTGCATCGGGCAGGCGTTCG CGATGGCGGAGATGAAGGTGGTCCTGGGGCTCACGCTGCTGCGCTTCCGCGTCCTGCCTGACCACACCGA GCCCCGCAGGAAGCCGGAGCTGGTCCTGCGCGCAGAGGGCGGACTTTGGCTGCGGGTGGAGCCCCTGAGC TGAGTTCTGCAGAGACCCACTCTGACCCCACTAAAATGACCCCTGATTCATCAAAAGTGAGGCCTAGAAT TACCCTAAGACCCTGTTCCACAGTCCTGTATTCCATCCTAGATATCTACTCAAAATAATTGAGACAAGTG TTCAAACAGAAAGACGCTTGTGCGTGAATGTTCATGGCAGCCCTATTCACAGTAGCCAAACGATGAAAAC AACCCCAAGCTATATATTACCAGATGAAAGGATAAACAAAATATGGTCCATCCATACAATGGAGTATTAC ACAGCCATAAAAAGGAATGAAGCAGTGATCCCCACTACACTGTGGATGAACCTTGAATGCATGATACTGA ATGAAAGACATCAGATGCAAAAGGTCACATAGTGTACTGTCCTTTTATATGAAATTTCCAGAACAGGCCA ATCTGAAGAGATGTATAGTGGATTGGTGGCTTTCAGCAGCTGTGGGGAGGTGGGACTGAGGAGCGACTGC TAATCAGGATGGGGTTTCCTCCTGGGATGGTGAAAATGTTCCGGACCTAGATAGTGATGAAGGTAGCACG ACACTGTGAGTGCACTAAATGCTATTGAATTGGACACTTTAGAATGGTTGAAATAGTGATTTTTATGTGA ATTCTACCTAAACATGCTATTACAGCTCATATATACTTTTTCCATCTGGATTCTTCACAAAAGAATATGT TGTGAGCATCTTTCCATGATATTAAATCATCTTAGGAAACATTATTTTGTGTTCTTCAAAATGTGCATGT TAAGTATTCAAATCAGTCTTAAATTTTTAAAAATATGTAATTTTAGAAAATAATTTAAAAGGTTTTGTTT CAGTTTGTAAGATTTCTTTTCTGGCACTTTAATGGCTTGAGGTATCATTATCAGTTACAAATTGAGTTAT TCTTCATCAAATGACTTTTGGAGTAGAGATTTTATTTTTATAGCAATAGATGCACAGATATTCCTGTAAG ATACAGGTGTGGTTAGACACTTTTCTAGAACAGGCATGCCCTGCAAACTCCACAGACACTGACTGTTTTT GTCCTATTAAGAAGTAGACCACTGAGAAGGGAGAAGGTGACATTTTAGCTTTCCCAGGTAAAAGTGGTTT TCATCCTCACACCAATTTTATGGACTGGACGTTAACTCTCTTGCTCAAGGTCACTCTGAGTGGAAGAGTG GGGATAAATCTGGTTCGTTTGGCATCAGAGGCCATGACTTTTCCTACCACAGAAGTAATTTTCAAAGTAA GTCTCTGCCCTAGGCACATCAGATCACCTGGGGACCACTCCAGAGTGAGTAGACAAGACTTTGACAGGGG TGCCTAATTTTTTTTTTTTTTTGAGATGGAGTCTCGCTCTGTTGCCCA (SEQ ID NO: 19) Translated protein sequence MPQLSLSSLGLWPMAASPWLLLLLVGASWLLARILAWTYTFYDN CCRLRCFPQPPKRNWFLGHLGLIHSSEEGLLYTQSLACTFGDMCCWWVGPWHAIVRIF HPTYIKPVLFAPAAIVPKDKVFYSFLKPWLGDGLLLSAGEKWSRHRRMLTPAFHFNIL KPYMKIFNESVNIMHAKWQLLASEGSARLDMFEHISLMTLDSLQKCVFSFDSHCQEKP SEYIAAILELSALVTKRHQQILLYIDFLYYLTPDGQRFRRACRLVHDFTDAVIQERRR TLPSQGVDDFLQAKAKSKTLDFIDVLLLSKDEDGKKLSDEDIRAEADTFMFEGHDTTA SGLSWVLYHLAKHPEYQERCRQEVQELLKDREPKEIEWDDLAQLPFLTMCIKESLRLH PPVPAVSRCCTQDIVLPDGRVIPKGIICLISVFGTHHNPAVWPDPEVYDPFRFDPKNI KERSPLAFIPFSAGPRNCIGQAFAMAEMKVVLGLTLLRFRVLPDHTEPRRKPELVLRA EGGLWLRVEPLS (SEQ ID NO: 20) DYSF 8291 NM_003494 Homo sapiens dysferlin, limb girdle muscular dystrophy 2B (autosomal recessive) (DYSF), transcript variant 8, mRNA mRNA Sequence GCGGCCGCCGCCCAGCCAGGTGCAAAATGCCGTGTCATTGGGAGACTCCGCAGCCGGAGCATTAGATTAC AGCTCGACGGAGCTCGGGAAGGGCGGCGGGGGTGGAAGATGAGCAGAAGCCCCTGTTCTCGGAACGCCGG CTGACAAGCGGGGTGAGCGCAGCCGGGGCGGGGACCCAGCCTAGCCCACTGGAGCAGCCGGGGGTGGCCC GTTCCCCTTTAAGAGCAACTGCTCTAAGCCAGGAGCCAGAGATTCGAGCCGGCCTCGCCCAGCCAGCCCT CTCCAGCGAGGGGACCCACAAGCGGCGCCTCGGCCCTCCCGACCTTTCCGAGCCCTCTTTGCGCCCTGGG CGCACGGGGCCCTACACGCGCCAAGCATGCTGAGGGTCTTCATCCTCTATGCCGAGAACGTCCACACACC CGACACCGACATCAGCGATGCCTACTGCTCCGCGGTGTTTGCAGGGGTGAAGAAGAGAACCAAAGTCATC AAGAACAGCGTGAACCCTGTATGGAATGAGGGATTTGAATGGGACCTCAAGGGCATCCCCCTGGACCAGG GCTCTGAGCTTCATGTGGTGGTCAAAGACCATGAGACGATGGGGAGGAACAGGTTCCTGGGGGAAGCCAA GGTCCCACTCCGAGAGGTCCTCGCCACCCCTAGTCTGTCCGCCAGCTTCAATGCCCCCCTGCTGGACACC AAGAAGCAGCCCACAGGGGCCTCGCTGGTCCTGCAGGTGTCCTACACACCGCTGCCTGGAGCTGTGCCCC TGTTCCCGCCCCCTACTCCTCTGGAGCCCTCCCCGACTCTGCCTGACCTGGATGTAGTGGCAGACACAGG AGGAGAGGAAGACACAGAGGACCAGGGACTCACTGGAGATGAGGCGGAGCCATTCCTGGATCAAAGCGGA GGCCCGGGGGCTCCCACCACCCCAAGGAAACTACCTTCACGTCCTCCGCCCCACTACCCCGGGATCAAAA GAAAGCGAAGTGCGCCTACATCTAGAAAGCTGCTGTCAGACAAACCGCAGGATTTCCAGATCAGGGTCCA GGTGATCGAGGGGCGCCAGCTGCCGGGGGTGAACATCAAGCCTGTGGTCAAGGTTACCGCTGCAGGGCAG ACCAAGCGGACGCGGATCCACAAGGGAAACAGCCCACTCTTCAATGAGACTCTTTTCTTCAACTTGTTTG ACTCTCCTGGGGAGCTGTTTGATGAGCCCATCTTTATCACGGTGGTAGACTCTCGTTCTCTCAGGACAGA TGCTCTCCTCGGGGAGTTCCGGATGGACGTGGGCACCATTTACAGAGAGCCCCGGCACGCCTATCTCAGG AAGTGGCTGCTGCTCTCAGACCCTGATGACTTCTCTGCTGGGGCCAGAGGCTACCTGAAAACAAGCCTTT GTGTGCTGGGGCCTGGGGACGAAGCGCCTCTGGAGAGAAAAGACCCCTCTGAAGACAAGGAGGACATTGA AAGCAACCTGCTCCGGCCCACAGGCGTAGCCCTGCGAGGAGCCCACTTCTGCCTGAAGGTCTTCCGGGCC GAGGACTTGCCGCAGATGGACGATGCCGTGATGGACAACGTGAAACAGATCTTTGGCTTCGAGAGTAACA AGAAGAACTTGGTGGACCCCTTTGTGGAGGTCAGCTTTGCGGGGAAAATGCTGTGCAGCAAGATCTTGGA GAAGACGGCCAACCCTCAGTGGAACCAGAACATCACACTGCCTGCCATGTTTCCCTCCATGTGCGAAAAA ATGAGGATTCGTATCATAGACTGGGACCGCCTGACTCACAATGACATCGTGGCTACCACCTACCTGAGTA TGTCGAAAATCTCTGCCCCTGGAGGAGAAATAGAAGAGGAGCCTGCAGGTGCTGTCAAGCCTTCGAAAGC CTCAGACTTGGATGACTACCTGGGCTTCCTCCCCACTTTTGGGCCCTGCTACATCAACCTCTATGGCAGT CCCAGAGAGTTCACAGGCTTCCCAGACCCCTACACAGAGCTCAACACAGGCAAGGGGGAAGGTGTGGCTT ATCGTGGCCGGCTTCTGCTCTCCCTGGAGACCAAGCTGGTGGAGCACAGTGAACAGAAGGTGGAGGACCT TCCTGCGGATGACATCCTCCGGGTGGAGAAGTACCTTAGGAGGCGCAAGTACTCCCTGTTTGCGGCCTTC TACTCAGCCACCATGCTGCAGGATGTGGATGATGCCATCCAGTTTGAGGTCAGCATCGGGAACTACGGGA ACAAGTTCGACATGACCTGCCTGCCGCTGGCCTCCACCACTCAGTACAGCCGTGCAGTCTTTGACGGGTG CCACTACTACTACCTACCCTGGGGTAACGTGAAACCTGTGGTGGTGCTGTCATCCTACTGGGAGGACATC AGCCATAGAATCGAGACTCAGAACCAGCTGCTTGGGATTGCTGACCGGCTGGAAGCTGGCCTGGAGCAGG TCCACCTGGCCCTGAAGGCGCAGTGCTCCACGGAGGACGTGGACTCGCTGGTGGCTCAGCTGACGGATGA GCTCATCGCAGGCTGCAGCCAGCCTCTGGGTGACATCCATGAGACACCCTCTGCCACCCACCTGGACCAG TACCTGTACCAGCTGCGCACCCATCACCTGAGCCAAATCACTGAGGCTGCCCTGGCCCTGAAGCTCGGCC ACAGTGAGCTCCCTGCAGCTCTGGAGCAGGCGGAGGACTGGCTCCTGCGTCTGCGTGCCCTGGCAGAGGA GCCCCAGAACAGCCTGCCGGACATCGTCATCTGGATGCTGCAGGGAGACAAGCGTGTGGCATACCAGCGG GTGCCCGCCCACCAAGTCCTCTTCTCCCGGCGGGGTGCCAACTACTGTGGCAAGAATTGTGGGAAGCTAC AGACAATCTTTCTGAAATATCCGATGGAGAAGGTGCCTGGCGCCCGGATGCCAGTGCAGATACGGGTCAA GCTGTGGTTTGGGCTCTCAGTGGATGAGAAGGAGTTCAACCAGTTTGCTGAGGGGAAGCTGTCTGTCTTT GCTGAAACCTATGAGAACGAGACTAAGTTGGCCCTTGTTGGGAACTGGGGCACAACGGGCCTCACCTACC CCAAGTTTTCTGACGTCACGGGCAAGATCAAGCTACCCAAGGACAGCTTCCGCCCCTCGGCCGGCTGGAC CTGGGCTGGAGATTGGTTCGTGTGTCCGGAGAAGACTCTGCTCCATGACATGGACGCCGGTCACCTGAGC TTCGTGGAAGAGGTGTTTGAGAACCAGACCCGGCTTCCCGGAGGCCAGTGGATCTACATGAGTGACAACT ACACCGATGTGAACGGGGAGAAGGTGCTTCCCAAGGATGACATTGAGTGCCCACTGGGCTGGAAGTGGGA AGATGAGGAATGGTCCACAGACCTCAACCGGGCTGTCGATGAGCAAGGCTGGGAGTATAGCATCACCATC CCCCCGGAGCGGAAGCCGAAGCACTGGGTCCCTGCTGAGAAGATGTACTACACACACCGACGGCGGCGCT GGGTGCGCCTGCGCAGGAGGGATCTCAGCCAAATGGAAGCACTGAAAAGGCACAGGCAGGCGGAGGCGGA GGGCGAGGGCTGGGAGTACGCCTCTCTTTTTGGCTGGAAGTTCCACCTCGAGTACCGCAAGACAGATGCC TTCCGCCGCCGCCGCTGGCGCCGTCGCATGGAGCCACTGGAGAAGACGGGGCCTGCAGCTGTGTTTGCCC TTGAGGGGGCCCTGGGCGGCGTGATGGATGACAAGAGTGAAGATTCCATGTCCGTCTCCACCTTGAGCTT CGGTGTGAACAGACCCACGATTTCCTGCATATTCGACTATGGGAACCGCTACCATCTACGCTGCTACATG TACCAGGCCCGGGACCTGGCTGCGATGGACAAGGACTCTTTTTCTGATCCCTATGCCATCGTCTCCTTCC TGCACCAGAGCCAGAAGACGGTGGTGGTGAAGAACACCCTTAACCCCACCTGGGACCAGACGCTCATCTT CTACGAGATCGAGATCTTTGGCGAGCCGGCCACAGTTGCTGAGCAACCGCCCAGCATTGTGGTGGAGCTG TACGACCATGACACTTATGGTGCAGACGAGTTTATGGGTCGCTGCATCTGTCAACCGAGTCTGGAACGGA TGCCACGGCTGGCCTGGTTCCCACTGACGAGGGGCAGCCAGCCGTCGGGGGAGCTGCTGGCCTCTTTTGA GCTCATCCAGAGAGAGAAGCCGGCCATCCACCATATTCCTGGTTTTGAGGTGCAGGAGACATCAAGGATC CTGGATGAGTCTGAGGACACAGACCTGCCCTACCCACCACCCCAGAGGGAGGCCAACATCTACATGGTTC CTCAGAACATCAAGCCAGCGCTCCAGCGTACCGCCATCGAGATCCTGGCATGGGGCCTGCGGAACATGAA GAGTTACCAGCTGGCCAACATCTCCTCCCCCAGCCTCGTGGTAGAGTGTGGGGGCCAGACGGTGCAGTCC TGTGTCATCAGGAACCTCCGGAAGAACCCCAACTTTGACATCTGCACCCTCTTCATGGAAGTGATGCTGC CCAGGGAGGAGCTCTACTGCCCCCCCATCACCGTCAAGGTCATCGATAACCGCCAGTTTGGCCGCCGGCC TGTGGTGGGCCAGTGTACCATCCGCTCCCTGGAGAGCTTCCTGTGTGACCCCTACTCGGCGGAGAGTCCA TCCCCACAGGGTGGCCCAGACGATGTGAGCCTACTCAGTCCTGGGGAAGACGTGCTCATCGACATTGATG ACAAGGAGCCCCTCATCCCCATCCAGGAGGAAGAGTTCATCGATTGGTGGAGCAAATTCTTTGCCTCCAT AGGGGAGAGGGAAAAGTGCGGCTCCTACCTGGAGAAGGATTTTGACACCCTGAAGGTCTATGACACACAG CTGGAGAATGTGGAGGCCTTTGAGGGCCTGTCTGACTTTTGTAACACCTTCAAGCTGTACCGGGGCAAGA CGCAGGAGGAGACAGAAGATCCATCTGTGATTGGTGAATTTAAGGGCCTCTTCAAAATTTATCCCCTCCC AGAAGACCCAGCCATCCCCATGCCCCCAAGACAGTTCCACCAGCTGGCCGCCCAGGGACCCCAGGAGTGC TTGGTCCGTATCTACATTGTCCGAGCATTTGGCCTGCAGCCCAAGGACCCCAATGGAAAGTGTGATCCTT ACATCAAGATCTCCATAGGGAAGAAATCAGTGAGTGACCAGGATAACTACATCCCCTGCACGCTGGAGCC CGTATTTGGAAAGATGTTCGAGCTGACCTGCACTCTGCCTCTGGAGAAGGACCTAAAGATCACTCTCTAT GACTATGACCTCCTCTCCAAGGACGAAAAGATCGGTGAGACGGTCGTCGACCTGGAGAACAGGCTGCTGT CCAAGTTTGGGGCTCGCTGTGGACTCCCACAGACCTACTGTGTCTCTGGACCGAACCAGTGGCGGGACCA GCTCCGCCCCTCCCAGCTCCTCCACCTCTTCTGCCAGCAGCATAGAGTCAAGGCACCTGTGTACCGGACA GACCGTGTAATGTTTCAGGATAAAGAATATTCCATTGAAGAGATAGAGGCTGGCAGGATCCCAAACCCAC ACCTGGGCCCAGTGGAGGAGCGTCTGGCTCTGCATGTGCTTCAGCAGCAGGGCCTGGTCCCGGAGCACGT GGAGTCACGGCCCCTCTACAGCCCCCTGCAGCCAGACATCGAGCAGGGGAAGCTGCAGATGTGGGTCGAC CTATTTCCGAAGGCCCTGGGGCGGCCTGGACCTCCCTTCAACATCACCCCACGGAGAGCCAGAAGGTTTT TCCTGCGTTGTATTATCTGGAATACCAGAGATGTGATCCTGGATGACCTGAGCCTCACGGGGGAGAAGAT GAGCGACATTTATGTGAAAGGTTGGATGATTGGCTTTGAAGAACACAAGCAAAAGACAGACGTGCATTAT CGTTCCCTGGGAGGTGAAGGCAACTTCAACTGGAGGTTCATTTTCCCCTTCGACTACCTGCCAGCTGAGC AAGTCTGTACCATTGCCAAGAAGGATGCCTTCTGGAGGCTGGACAAGACTGAGAGCAAAATCCCAGCACG AGTGGTGTTCCAGATCTGGGACAATGACAAGTTCTCCTTTGATGATTTTCTGGGCTCCCTGCAGCTCGAT CTCAACCGCATGCCCAAGCCAGCCAAGACAGCCAAGAAGTGCTCCTTGGACCAGCTGGATGATGCTTTCC ACCCAGAATGGTTTGTGTCCCTTTTTGAGCAGAAAACAGTGAAGGGCTGGTGGCCCTGTGTAGCAGAAGA GGGTGAGAAGAAAATACTGGCGGGCAAGCTGGAAATGACCTTGGAGATTGTAGCAGAGAGTGAGCATGAG GAGCGGCCTGCTGGCCAGGGCCGGGATGAGCCCAACATGAACCCTAAGCTTGAGGACCCAAGGCGCCCCG ACACCTCCTTCCTGTGGTTTACCTCCCCATACAAGACCATGAAGTTCATCCTGTGGCGGCGTTTCCGGTG GGCCATCATCCTCTTCATCATCCTCTTCATCCTGCTGCTGTTCCTGGCCATCTTCATCTACGCCTTCCCG AACTATGCTGCCATGAAGCTGGTGAAGCCCTTCAGCTGAGGACTCTCCTGCCCTGTAGAAGGGGCCGTGG GGTCCCCTCCAGCATGGGACTGGCCTGCCTCCTCCGCCCAGCTCGGCGAGCTCCTCCAGACCTCCTAGGC CTGATTGTCCTGCCAGGGTGGGCAGACAGACAGATGGACCGGCCCACACTCCCAGAGTTGCTAACATGGA GCTCTGAGATCACCCCACTTCCATCATTTCCTTCTCCCCCAACCCAACGCTTTTTTGGATCAGCTCAGAC ATATTTCAGTATAAAACAGTTGGAACCACAAAAAAAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 21) Translated protein sequence MLRVFILYAENVHTPDTDISDAYCSAVFAGVKKRTKVIKNSVNP VWNEGFEWDLKGIPLDQGSELHVVVKDHETMGRNRFLGEAKVPLREVLATPSLSASFN APLLDTKKQPTGASLVLQVSYTPLPGAVPLFPPPTPLEPSPTLPDLDVVADTGGEEDT EDQGLTGDEAEPFLDQSGGPGAPTTPRKLPSRPPPHYPGIKRKRSAPTSRKLLSDKPQ DFQIRVQVIEGRQLPGVNIKPWKVTAAGQTKRTRIHKGNSPLFNETLFFNLFDSPGE LFDEPIFITVVDSRSLRTDALLGEFRMDVGTIYREPRHAYLRKWLLLSDPDDFSAGAR GYLKTSLCVLGPGDEAPLERKDPSEDKEDIESNLLRPTGVALRGAHFCLKVFRAEDLP QMDDAVMDNVKQIFGFESNKKNLVDPFVEVSFAGKMLCSKILEKTANPQWNQNITLPA MFPSMCEKMRIRIIDWDRLTHNDIVATTYLSMSKISAPGGEIEEEPAGAVKPSKASDL DDYLGFLPTFGPCYINLYGSPREFTGFPDPYTELNTGKGEGVAYRGRLLLSLETKLVE HSEQKVEDLPADDILRVEKYLRRRKYSLFAAFYSATMLQDVDDAIQFEVSIGNYGNKF DMTCLPLASTTQYSRAVFDGCHYYYLPWGNVKPVVVLSSYWEDISHRIETQNQLLGIA DRLEAGLEQVHLALKAQCSTEDVDSLVAQLTDELIAGCSQPLGDIHETPSATHLDQYL YQLRTHHLSQITEAALALKLGHSELPAALEQAEDWLLRLRALAEEPQNSLPDIVIWML QGDKRVAYQRVPAHQVLFSRRGANYCGKNCGKLQTIFLKYPMEKVPGARMPVQIRVKL WFGLSVDEKEFNQFAEGKLSVFAETYENETKLALVGNWGTTGLTYPKFSDVTGKIKLP KDSFRPSAGWTWAGDWFVCPEKTLLHDMDAGHLSFVEEVFENQTRLPGGQWIYMSDNY TDVNGEKVLPKDDIECPLGWKWEDEEWSTDLNRAVDEQGWEYSITIPPERKPKHWVPA EKMYYTHRRRRWVRLRRRDLSQMEALKRHRQAEAEGEGWEYASLFGWKFHLEYRKTDA FRRRRWRRRMEPLEKTGPAAVFALEGALGGVMDDKSEDSMSVSTLSFGVNRPTISCIF DYGNRYHLRCYMYQARDLAAMDKDSFSDPYAIVSFLHQSQKTVVVKNTLNPTWDQTLI FYEIEIFGEPATVAEQPPSIVVELYDHDTYGADEFMGRCICQPSLERMPRLAWFPLTR GSQPSGELLASFELIQREKPAIHHIPGFEVQETSRILDESEDTDLPYPPPQREANIYM VPQNIKPALQRTAIEILAWGLRNMKSYQLANISSPSLVVECGGQTVQSCVIRNLRKNP NFDICTLFMEVMLPREELYCPPITVKVIDNRQFGRRPVVGQCTIRSLESFLCDPYSAE SPSPQGGPDDVSLLSPGEDVLIDIDDKEPLIPIQEEEFIDWWSKFFASIGEREKCGSY LEKDFDTLKVYDTQLENVEAFEGLSDFCNTFKLYRGKTQEETEDPSVIGEFKGLFKIY PLPEDPAIPMPPRQFHQLAAQGPQECLVRIYIVRAFGLQPKDPNGKCDPYIKISIGKK SVSDQDNYIPCTLEPVFGKMFELTCTLPLEKDLKITLYDYDLLSKDEKIGETVVDLEN RLLSKFGARCGLPQTYCVSGPNQWRDQLRPSQLLHLFCQQHRVKAPVYRTDRVMFQDK EYSIEEIEAGRIPNPHLGPVEERLALHVLQQQGLVPEHVESRPLYSPLQPDIEQGKLQ MWVDLFPKALGRPGPPFNITPRRARRFFLRCIIWNTRDVILDDLSLTGEKMSDIYVKG WMIGFEEHKQKTDVHYRSLGGEGNFNWRFIFPFDYLPAEQVCTIAKKDAFWRLDKTES KIPARVVFQIWDNDKFSFDDFLGSLQLDLNRMPKPAKTAKKCSLDQLDDAFHPEWFVS LFEQKTVKGWWPCVAEEGEKKILAGKLEMTLEIVAESEHEERPAGQGRDEPNMNPKLE DPRRPDTSFLWFTSPYKTMKFILWRRFRWAIILFIILFILLLFLAIFIYAFPNYAAMK LVKPFS (SEQ ID NO: 22) EDIL3 10085 NM_005711 Homo sapiens EGF-like repeats and discoidin I- like domains 3 (EDIL3), mRNA mRNA Sequence AGAAGCCCCGCAGCCGCCGCGCGGAGAACAGCGACAGCCGAGCGCCCGGTCCGCCTGTCTGCCGGTGGGT CTGCCTGCCCGCGCAGCAGACCCGGGGCGGCCGCGGGAGCCCGCGCCCCGCCCGCCGCGCCTCTGCCGGG ACCCACCCGCAGCGGAGGGCTGAGCCCGCCGGCGGCTCCCCGGAGCTCACCCACCTCCGCGCGCCGGAGC GCAGGCAAAAGGGGAGGAAAGGCTCCTCTCTTTAGTCACCACTCTCGCCCTCTCCAAGAATTTGTTTAAC AAAGCGCTGAGGAAAGAGAACGTCTTCTTGAATTCTTTAGTAGGGGCGGAGTCTGCTGCTGCCCTGCGCT GCCACCTCGGCTACACTGCCCTCCGCGACGACCCCTGACCAGCCGGGGTCACGTCCGGGAGACGGGATCA TGAAGCGCTCGGTAGCCGTCTGGCTCTTGGTCGGGCTCAGCCTCGGTGTCCCCCAGTTCGGCAAAGGTGA TATTTGTGATCCCAATCCATGTGAAAATGGAGGTATCTGTTTGCCAGGATTGGCTGATGGTTCCTTTTCC TGTGAGTGTCCAGATGGCTTCACAGACCCCAACTGTTCTAGTGTTGTGGAGGTTGCATCAGATGAAGAAG AACCAACTTCAGCAGGTCCCTGCACTCCTAATCCATGCCATAATGGAGGAACCTGTGAAATAAGTGAAGC ATACCGAGGGGATACATTCATAGGCTATGTTTGTAAATGTCCCCGAGGATTTAATGGGATTCACTGTCAG CACAACATAAATGAATGCGAAGTTGAGCCTTGCAAAAATGGTGGAATATGTACAGATCTTGTTGCTAACT ATTCCTGTGAGTGCCCAGGCGAATTTATGGGAAGAAATTGTCAATACAAATGCTCAGGCCCACTGGGAAT TGAAGGTGGAATTATATCAAACCAGCAAATCACAGCTTCCTCTACTCACCGAGCTCTTTTTGGACTCCAA AAATGGTATCCCTACTATGCACGTCTTAATAAGAAGGGGCTTATAAATGCGTGGACAGCTGCAGAAAATG ACAGATGGCCGTGGATTCAGATAAATTTGCAAAGGAAAATGAGAGTTACTGGTGTGATTACCCAAGGAGC CAAGAGGATTGGAAGCCCAGAGTATATAAAATCCTACAAAATTGCCTACAGTAATGATGGAAAGACTTGG GCAATGTACAAAGTGAAAGGCACCAATGAAGACATGGTGTTTCGTGGAAACATTGATAACAACACTCCAT ATGCTAACTCTTTCACACCCCCCATAAAAGCTCAGTATGTAAGACTCTATCCCCAAGTTTGTCGAAGACA TTGCACTTTGCGAATGGAACTTCTTGGCTGTGAACTGTCGGGTTGTTCTGAGCCTCTGGGTATGAAATCA GGACATATACAAGACTATCAGATCACTGCCTCCAGCATCTTCAGAACGCTCAACATGGACATGTTCACTT GGGAACCAAGGAAAGCTCGGCTGGACAAGCAAGGCAAAGTGAATGCCTGGACCTCTGGCCACAATGACCA GTCACAATGGTTACAGGTGGATCTTCTTGTTCCAACCAAAGTGACTGGCATCATTACACAAGGAGCTAAA GATTTTGGTCATGTACAGTTTGTTGGCTCCTACAAACTGGCTTACAGCAATGATGGAGAACACTGGACTG TATACCAGGATGAAAAGCAAAGAAAAGATAAGGTTTTCCAGGGAAATTTTGACAATGACACTCACAGAAA AAATGTCATCGACCCTCCCATCTATGCACGACACATAAGAATCCTTCCTTGGTCCTGGTACGGGAGGATC ACATTGCGGTCAGAGCTGCTGGGCTGCACAGAGGAGGAATGAGGGGAGGCTACATTTCACAACCCTCTTC CCTATTTCCCTAAAAGTATCTCCATGGAATGAACTGTGCAAAATCTGTAGGAAACTGAATGGTTTTTTTT TTTTTTTCATGAAAAAGTGCTCAAATTATGGTAGGCAACTAACGGTGTTTTTAAGGGGGTCTAAGCCTGC CTTTTCAATGATTTAATTTGATTTTATTTTATCCGTCAAATCTCTTAAGTAACAACACATTAAGTGTGAA TTACTTTTCTCTCATTGTTTCCTGAATTATTCGCATTGGTAGAAATATATTAGGGAAAGAAAGTAGCCTT CTTTTTATAGCAAGAGTAAAAAAGTCTCAAAGTCATCAAATAAGAGCAAGAGTTGATAGAGCTTTTACAA TCAATACTCACCTAATTCTGATAAAAGGAATACTGCAATGTTAGCAATAAGTTTTTTTCTTCTGTAATGA CTCTACGTTATCCTGTTTCCCTGTGCCTACCAAACACTGTCAATGTTTATTACAAAATTTTAAAGAAGAA TATGTAACATGCAGTACTGATATTATAATTCTCATTTTACTTTCATTATTTCTAATAAGAGATTATGTGA CTTCTTTTTCTTTTAGTTCTATTCTACATTCTTAATATTGTATATTACCTGAATAATTCAATTTTTTTCT AATTGAATTTCCTATTAGTTGACTAAAAGAAGTGTCATGTTTACTCATATATGTAGAACATGACTGCCTA TCAGTAGATTGATCTGTATTTAATATTCGTTAATTAAATCTGCAGTTTTATTTTTGAAGGAAGCCATAAC TATTTAATTTCCAAATAATTGCTTCATAAAGAATCCCATACTCTCAGTTTGCACAAAAGAACAAAAAATA TATATGTCTCTTTAAATTTAAATCTTCATTTAGATGGTAATTACATATCCTTATATTTACTTTAAAAAAT CGGCTTATTTGTTTATTTTATAAAAAATTTAGCAAAGAAATATTAATATAGTGCTGCATAGTTTGGCCAA GCATACTCATCATTTCTTTGTTCAGCTCCACATTTCCTGTGAAACTAACATCTTATTGAGATTTGAAACT GGTGGTAGTTTCCCAGGAAGGCACAGGTGGAGTT (SEQ ID NO: 23) Translated protein sequence MKRSVAVWLLVGLSLGVPQFGKGDICDPNPCENGGICLPGLADG SFSCECPDGFTDPNCSSVVEVASDEEEPTSAGPCTPNPCHNGGTCEISEAYRGDTFIG YVCKCPRGFNGIHCQHNINECEVEPCKNGGICTDLVANYSCECPGEFMGRNCQYKCSG PLGIEGGIISNQQITASSTHRALFGLQKWYPYYARLNKKGLINAWTAAENDRWPWIQI NLQRKMRVTGVITQGAKRIGSPEYIKSYKIAYSNDGKTWAMYKVKGTNEDMVFRGNID NNTPYANSFTPPIKAQYVRLYPQVCRRHCTLRMELLGCELSGCSEPLGMKSGHIQDYQ ITASSIFRTLNMDMFTWEPRKARLDKQGKVNAWTSGHNDQSQWLQVDLLVPTKVTGII TQGAKDFGHVQFVGSYKLAYSNDGEHWTVYQDEKQRKDKVFQGNFDNDTHRKNVIDPP IYARHIRILPWSWYGRITLRSELLGCTEEE (SEQ ID NO: 24) ERGIC3 51614 NM_015966 Homo sapiens ERGIC and golgi 3 (ERGIC3), transcript variant 2, mRNA mRNA Sequence GTGGCTCCAGGCCGGAAGAGGGAGTCTGTAGGGGCGGGCCGGCTGGCGTCCCCTTTCCGGCCGGTCCCCA TGGAGGCGCTGGGGAAGCTGAAGCAGTTCGATGCCTACCCCAAGACTTTGGAGGACTTCCGGGTCAAGAC CTGCGGGGGCGCCACCGTGACCATTGTCAGTGGCCTTCTCATGCTGCTACTGTTCCTGTCCGAGCTGCAG TATTACCTCACCACGGAGGTGCATCCTGAGCTCTACGTGGACAAGTCGCGGGGAGATAAACTGAAGATCA ACATCGATGTACTTTTTCCGCACATGCCTTGTGCCTATCTGAGTATTGATGCCATGGATGTGGCCGGAGA ACAGCAGCTGGATGTGGAACACAACCTGTTCAAGCAACGACTAGATAAAGATGGCATCCCCGTGAGCTCA GAGGCTGAGCGGCATGAGCTTGGGAAAGTCGAGGTGACGGTGTTTGACCCTGACTCCCTGGACCCTGATC GCTGTGAGAGCTGCTATGGTGCTGAGGCAGAAGATATCAAGTGCTGTAACACCTGTGAAGATGTGCGGGA GGCATATCGCCGTAGAGGCTGGGCCTTCAAGAACCCAGATACTATTGAGCAGTGCCGGCGAGAGGGCTTC AGCCAGAAGATGCAGGAGCAGAAGAATGAAGGCTGCCAGGTGTATGGCTTCTTGGAAGTCAATAAGGTGG CCGGAAACTTCCACTTTGCCCCTGGGAAGAGCTTCCAGCAGTCCCATGTGCACGTCCATGACTTGCAGAG CTTTGGCCTTGACAACATCAACATGACCCACTACATCCAGCACCTGTCATTTGGGGAGGACTATCCAGGC ATTGTGAACCCCCTGGACCACACCAATGTCACTGCGCCCCAAGCCTCCATGATGTTCCAGTACTTTGTGA AGGTGGTGCCCACTGTGTACATGAAGGTGGACGGAGAGGTACTGAGGACAAATCAGTTCTCTGTGACCAG ACATGAGAAGGTTGCCAATGGGCTGTTGGGCGACCAAGGCCTTCCCGGAGTCTTCGTCCTCTATGAGCTC TCGCCCATGATGGTGAAGCTGACGGAGAAGCACAGGTCCTTCACCCACTTCCTGACAGGTGTGTGCGCCA TCATTGGGGGCATGTTCACAGTGGCTGGACTCATCGATTCGCTCATCTACCACTCAGCACGAGCCATCCA GAAGAAAATTGATCTAGGGAAGACAACGTAGTCACCCTCGGTGCTTCCTCTGTCTCCTCTTTCTCCCTGG CCTGTGGTTGTCCCCCAGCCTCTGCCACCCTCCACCTCCTCGGTCAGCCCCAGCCCCAGGTTGATAAATC TATTGATTGATTGTGATAGTAAAAAAAAAAAAAAAAAA (SEQ ID NO: 25) Translated protein sequence MEALGKLKQFDAYPKTLEDFRVKTCGGATVTIVSGLLMLLLFLS ELQYYLTTEVHPELYVDKSRGDKLKINIDVLFPHMPCAYLSIDAMDVAGEQQLDVEHN LFKQRLDKDGIPVSSEAERHELGKVEVTVFDPDSLDPDRCESCYGAEAEDIKCCNTCE DVREAYRRRGWAFKNPDTIEQCRREGFSQKMQEQKNEGCQVYGFLEVNKVAGNFHFAP GKSFQQSHVHVHDLQSFGLDNINMTHYIQHLSFGEDYPGIVNPLDHTNVTAPQASMMF QYFVKVVPTVYMKVDGEVLRTNQFSVTRHEKVANGLLGDQGLPGVFVLYELSPMMVKL TEKHRSFTHFLTGVCAIIGGMFTVAGLIDSLIYHSARAIQKKIDLGKTT (SEQ ID NO: 26) GNAT1 2779 NM_000172 Homo sapiens guanine nucleotide binding protein (G protein), alpha transducing activity polypeptide 1 (GNAT1), transcript variant 2, mRNA mRNA Sequence AGTTGATTGCAGGTCCTCCTGGGGCCAGAAGGGTGCCTGGGAGGCCAGGTTCTGGGGATCCCCTCCATCC AGAAGAACCACCTGCTCACTCTGTCCCTTCGCCTGCTGCTGGGACCATGGGGGCTGGGGCCAGTGCTGAG GAGAAGCACTCCAGGGAGCTGGAAAAGAAGCTGAAAGAGGACGCTGAGAAGGATGCTCGAACCGTGAAGC TGCTGCTTCTGGGTGCCGGTGAGTCCGGGAAGAGCACCATCGTCAAGCAGATGAAGATTATCCACCAGGA CGGGTACTCGCTGGAAGAGTGCCTCGAGTTTATCGCCATCATCTACGGCAACACGTTGCAGTCCATCCTG GCCATCGTACGCGCCATGACCACACTCAACATCCAGTACGGAGACTCTGCACGCCAGGACGACGCCCGGA AGCTGATGCACATGGCAGACACTATCGAGGAGGGCACGATGCCCAAGGAGATGTCGGACATCATCCAGCG GCTGTGGAAGGACTCCGGTATCCAGGCCTGTTTTGAGCGCGCCTCGGAGTACCAGCTCAACGACTCGGCG GGCTACTACCTCTCCGACCTGGAGCGCCTGGTAACCCCGGGCTACGTGCCCACCGAGCAGGACGTGCTGC GCTCGCGAGTCAAGACCACTGGCATCATCGAGACGCAGTTCTCCTTCAAGGATCTCAACTTCCGGATGTT CGATGTGGGCGGGCAGCGCTCGGAGCGCAAGAAGTGGATCCACTGCTTCGAGGGCGTGACCTGCATCATC TTCATCGCGGCGCTGAGCGCCTACGACATGGTGCTAGTGGAGGACGACGAAGTGAACCGCATGCACGAGA GCCTGCACCTGTTCAACAGCATCTGCAACCACCGCTACTTCGCCACGACGTCCATCGTGCTCTTCCTTAA CAAGAAGGACGTCTTCTTCGAGAAGATCAAGAAGGCGCACCTCAGCATCTGTTTCCCGGACTACGATGGA CCCAACACCTACGAGGACGCCGGCAACTACATCAAGGTGCAGTTCCTCGAGCTCAACATGCGGCGCGACG TGAAGGAGATCTATTCCCACATGACGTGCGCCACCGACACGCAGAACGTCAAATTTGTCTTCGACGCTGT CACCGACATCATCATCAAGGAGAACCTCAAAGACTGTGGCCTCTTCTGAGGCCAGGGCCTGTGCTGCAGT CGGGGACAAGGAGCTTCCGTCTGGCAAGGCCGGGGCACAATTTGCACTCCCCTCAGCTAGACGCACAGAC TCAGCAATAAACCTTTGCATCAGGCTCCAGCTGTCCTTTCTTGGTGGAGGACTTAATTATCACAAGTCAT GGGCATTTATTAAGTGCCCAGTGCTGGGTTGGGCATGAAGTGGGAAGATGGCCCCTCCCAGGAAGAAGTA CCTGGCCTGACAAGGTGGGGCACTCTTGGGGGTATGGGACCAACTCATGGCTTTTCACGGGAGTTGAGGA GAGAGGAGCTGTGGAAAATATTCACTGGGACAGTCTTGGATCAAGAGGGAGTTTTGAGGTGGAGGCTCAT TCTGGCAGGGACCGTAGTGTCTACCAGCCCCAGAAACATGGGCTTATGGCCACAGGAGTTCAGTGGAGCA AGAGCAGGGGAGGAGAGACGTGGACAGGTGCCCAAAGCCAGTCGGAGGGCCTGGGCTTTCTCAGAAGGTG ATGGAGAGTCTTGGAAGCCCTCGAGGCAGGAACATAATTGCAGGGCTGGGATTAGGGTGAGGGAAGTGAG GCACACTCACCTTGGGTGCAACATTTAAGGCGATGCCAAAAAATTTAGTAACCAAGGTAAATAATATTAG GATAATATTTTTAAAAATCAAATGAATGCAAAACCCCACAATGAATGAAATATCAAAATCCAACAGAGGA TCAAACAGAGGCATGCTAAGATATATTGGGGCTTGAAGCAAAGGGAAAACTATTTGTTGCTATATGTTTG TAGGGATTTTTTGCCAGTTTTAAAAATACATGTATCATAAAGTTTACTATCTCAGCCACTTGCCGGTGTA TAGTTTGGTGGTGTTAAGTACATTCATAATGTTGTACAACCACCGCAACTGTTCATCTCCAGAACTCCTT TCCTCTTGTAAAACTGTAACTCTGTACCCATGAAAAAATAACCCCCCATTCCTGCCTTCCCCCGGCTCCT GGCATCCACCATTCTACTTTCCATCTCTATGAATGTGACTGCTCTAAGTGCCTCAGATGTGTGGGTCCAT GAAGTCTTTGTCTTTTTGCAACTGGCTTATTTCACTTAGCATCATGTCTTCAAGGTTTATTCATGTGTAG CATATGGCAGAATCTCCTTCCTTTTTAAGGTTGAATAATATTCCATTGTATATATTCCACACTTTGTTTA TTTATTCATCTATTGATGAATGGTTACATCTGCCTTTTGGCTATTGTGAATAATGCTGCTATGAACATGG GTGTACAAATCTCTCAAAAAAAAAAAAAAAAAA (SEQ ID NO: 27) Translated protein sequence MGAGASAEEKHSRELEKKLKEDAEKDARTVKLLLLGAGESGKST IVKQMKIIHQDGYSLEECLEFIAIIYGNTLQSILAIVRAMTTLNIQYGDSARQDDARK LMHMADTIEEGTMPKEMSDIIQRLWKDSGIQACFERASEYQLNDSAGYYLSDLERLVT PGYVPTEQDVLRSRVKTTGIIETQFSFKDLNFRMFDVGGQRSERKKWIHCFEGVTCII FIAALSAYDMVLVEDDEVNRMHESLHLFNSICKHRYFATTSIVLFLNKKDVFFEKIKK AHLSICFPDYDGPNTYEDAGNYIKVQFLELNMRRDVKEIYSHMTCATDTQNVKFVFDA VTDIIIKENLKDCGLF (SEQ ID NO: 28) GRAMD4 23151 NM_015124 Homo sapiens GRAM domain containing 4 (GRAMD4), mRNA mRNA Sequence CGTCATGTTAGGGTGAAGCAGAGGACCTCAGTGCTGAACATGCTAAGGAGGTTGGACAAAATCAGGTTCA GAGGTCACAAGAGAGATGACTTCCTCGATCTAGCGGAGTCTCCAAATGCCTCGGACACCGAATGCAGCGA CGAAATCCCCCTGAAGGTACCGCGGACCTCGCCCCGGGACAGCGAGGAGCTGAGGGACCCTGCTGGTCCA GGGACCCTCATCATGGCCACAGGAGTCCAGGACTTTAACCGGACAGAGTTTGATCGACTGAATGAGATCA AAGGTCACCTGGAAATTGCCTTATTGGAAAAACATTTCTTACAGGAGGAGCTCCGGAAGCTGCGAGAAGA AACCAACGCGGAGATGCTGCGGCAGGAGCTGGACCGCGAGCGGCAGCGGCGGATGGAGCTGGAGCAGAAG GTGCAGGAGGTGCTGAAGGCCAGAACCGAGGAGCAGATGGCTCAGCAGCCCCCAAAAGGGCAGGCCCAGG CCAGCAATGGAGCAGAGCGCCGGAGCCAGGGGCTGTCCTCGCGCCTGCAGAAGTGGTTCTACGAGCGGTT CGGGGAGTACGTGGAGGACTTCCGGTTCCAGCCCGAGGAGAACACTGTGGAGACAGAGGAACCCCTGAGC GCCCGCAGGTTAACTGAAAATATGAGACGGCTCAAGCGCGGTGCCAAGCCGGTCACTAACTTTGTGAAGA ACCTCTCTGCCTTATCCGACTGGTACTCCGTCTACACGTCTGCCATTGCCTTCACCGTGTACATGAATGC CGTGTGGCATGGCTGGGCCATCCCATTGTTCTTATTTCTAGCAATTCTGAGGTTATCCCTCAATTACCTC ATCGCCAGGGGGTGGCGGATACAGTGGAGCATCGTGCCCGAAGTGTCTGAGCCCGTGGAACCTCCAAAGG AAGACCTGACTGTGTCTGAGAAGTTCCAGCTGGTGCTGGACGTCGCCCAGAAAGCCCAGAACCTTTTCGG GAAGATGGCTGACATCCTGGAGAAGATCAAGAACTTGTTCATGTGGGTCCAGCCGGAGATCACACAGAAG CTGTATGTGGCGCTCTGGGCTGCCTTCCTGGCCTCCTGCTTCTTCCCCTACCGCCTGGTGGGGCTTGCCG TGGGACTCTATGCTGGTATCAAGTTCTTCCTCATTGATTTCATCTTTAAACGCTGCCCGAGGCTGCGCGC CAAGTACGACACGCCCTATATCATCTGGAGGAGTCTCCCCACCGACCCGCAGCTCAAGGAGCGCTCCAGC GCCGCAGTCTCACGCAGGCTGCAGACGACCTCGTCACGGAGCTACGTACCCAGCGCACCGGCCGGCCTGG GTAAAGAGGAGGACGCCGGTCGCTTCCACAGCACCAAGAAGGGCAATTTCCACGAGATCTTCAATCTGAC AGAAAACGAGCGTCCGCTGGCGGTGTGCGAGAATGGCTGGCGCTGCTGCCTCATCAACAGGGACCGGAAG ATGCCCACGGACTACATCAGGAACGGGGTGCTCTACGTCACGGAGAATTACTTGTGCTTCGAAAGCTCCA AATCTGGGTCCTCAAAGAGGAACAAAGTCATCAAGCTAGTGGACATCACGGACATCCAGAAGTACAAGGT CCTGTCTGTCCTCCCAGGCTCAGGCATGGGGATTGCCGTGTCGACGCCATCCACCCAGAAACCGCTCGTG TTTGGTGCCATGGTGCACAGGGATGAGGCCTTCGAGACCATTCTCAGCCAGTACATCAAGATCACCTCAG CGGCAGCGTCTGGCGGGGACAGCTAGTATTGACTTGCCCAGGACGTTGCTGGAATTTTCTTTTTCTTTTT CTTTTTCTTTTTTTTTTTTTACGATTTGGTAGTGGAAACAATTGGACATCCTCATGAGCTTTTGCAATAA TTCTCCTGGACCTGTGGTTCTATTGTGTTGACCTCTGCGTTTTATCGACCAAGAAGGGGCCAGGGCTCAC AGGGACGGGGGTGCCCCTCTCCCACAGGGCACGTCAGGTGCCTCTGAGGGCCACCCGCAGACTGGGGGAG GGGGCAGAGGCCCTCGGGGGCCCGTGGAGAAGACACACAGGACCCCTGGCCCTGCCCTTCTCCGTTCCAG CCTGGACAGAGAAACCTCTCCAGCCACCCCAAGAGGTTCTCGCAACCTTGTGTCCCGCTCTCCAGAGGCC AGAAGCTCGTCCACCACCAAAGCCATAGCTGAAGAGTGCGGGGCCCTTCCTCCTGGGGACAGAAAGATGT CGTCAAGGAGGGACATGGGGGCCTTTCACCAACCACCGAGAAACGGGCCTGGCGGCCCTCCTTCCTCTTA CATGAGACCCTCCTGTGGCATTTGCCCTTGGTGCCGGGCTGGGGCCGGGCGCAGTGACCCTGCCTGCGCT CCACACTCGCTCCACGGGAACAGAGAGGGTGAGAAGGGCCCACCCCTCGCCTGCCCTCAGTGTCTTTGGT GGCACCTTCCTTGCTGGCCTCCAGGGCGCTCAGCACCGCGTCTGTAAGGGCCTGCCTGCTGCTCTCGGCC TGACACGCCGGCCAGGAGGTCTGTAGCTGGGGACCAGTAAGGGCACAGGATGGTGCAGGTAAAAGCACAT CTTTCTCACACTTTGCTCTTTGGAAGGCCCAGGAGAACATCCGCGAAGGCTGTTGGAGGTGCTCCGAGCA CTGTGGCATGTCTGGCACATGGCCCCCAGGCTGCGGTTGCCTGGGTTGGTTGGGGGAGGAAGTGGGGAGG AGTGTTCCGGGACCATGGTGGCCCAGGCTGCAGCCGCCTTTGGGCCATCCGAGAGGCTCTGGCAGCCCCT GTGCTTTAGGGAGCAACCGTGAGCCGAGCCCAGAGGCCTGGGCCTGCACTGCCTGCAGCCGACATGCGAC AGCGTTCCCTCCCCCGCGTGCCTAGCCGGTGCCGGTCCGGGCACAGACCCCCCCAGCCCCCGCCCTGCCC CAGGGAAGCCTGGGCTTCCCGGGAACAAGGTGGCATTTGTGGAGGGAGCGCCCGCAGGCCTGGTCTGCTG GGGCCGCCTGCGCTGGGCTGAAGGGAGGGAAAGGCGGCTTGGGCCTCCTGGAAGGAGGTGGCCACCCCGC GGGCCTGCGTGTCTGCTGGGGCGGATCCCGCAGCTCCCTCAGCTTGTCCTGAGTCCCTTGGGTGTCGTTG AGATTGTTGTTTTTTGAAGAAACAGAAGATTCTATTTTTTACAGCGAGCAAGCTGGTTTTCTTATTTTTG TATCCTTTTTCAGATGTAATTTTTATCTTTGCTCCGATCCTCATTTGCTGGTGTGGGTGAGGGATCCGGC GGCATGGGCTGGTTTCACCCCCTTCACGAGGGGCCGCAGAGTCACACGCTGGTGCCGGGGGTGCTTTGGG GGGAGCTGCGCCGATCACCAGATTAAGCACATGTCCTATCCCAGGCGGTGGAGCGGAGCCCCCGTGGCTC TGGACTGCGCGGACGTTGGCGTCAGGATGACCACACGGCGGCCTTTCCCGAATGGGGACAGAACCCGCTC TGAGCCGTGGGTCTGGCTCCTGTAGGGGACTGGCTCTCTTGGTGCACCAGGGGAGGGGGACATATCCCAG TGAACCCCACCTTGGCGCCTGAGGCAACACAGGGTGGGCACTGACCCACCCCCAGGGGCGGCTGCAGAGG CAGTGCCCGCAGACAATGGCCACACCTCTCTCCCCAGGGCCCGGCAGTGCCCAAGGATGGGTCCGGGGCC TCGGGGCCAATGAGCGCCTCTTCCTAGGTGCTGGGATTCAGTCCCCAAACACAGCGGGAGGGGTCCCTGG GGCAGATGGGGCTTTACCAGCGTCGGGTGGTTTAGTTCGAGTCCCTTTTGTGGAGAAAGGGAGATGAAAA CTGACCACGTGCCAGGTGTGGCCGAAGCCCCCAGGGAGGGCCACATTCGGGGAGCGGGGGGTCGGGGGAG GGCCACCGACTGGCTCTGCTGCCAGCACAGGCCCCTCCCTGGAAGTCCTCGGGAGCGGAGCGCGGATCGG CACGGGCTCTGGGCTCCCCGTGGAGAGAAGCTGTAGTTTTTACCAAATTGTGTACATCTGGGCAGATGTT TAATTTCTGTGACTAATCACTGAACTAGACGAATGTTAAATTTTTTATGTCTGAAGCCTGAGTCTATTTT GGATCTGTAAATAATCATTGCCAGTGTGACTTTTGTTCAACAAAAGGATTGTACTGTATTAAGAACCGAT GAAAAAAATTCTCCTGTAACATTTTTTTAAGAAAACTTTGTTTGTTTAAAGAAAAAGTATTGTATAAATT ATAATTTTTATTTAAATAAACCTAAAATGCTTTGTGCTAAGGCTCAAAAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 29) Translated protein sequence MLRRLDKIRFRGHKRDDFLDLAESPNASDTECSDEIPLKVPRTS PRDSEELRDPAGPGTLIMATGVQDFNRTEFDRLNEIKGHLEIALLEKHFLQEELRKLR EETNAEMLRQELDRERQRRMELEQKVQEVLKARTEEQMAQQPPKGQAQASNGAERRSQ GLSSRLQKWFYERFGEYVEDFRFQPEENTVETEEPLSARRLTENMRRLKRGAKPVTNF VKNLSALSDWYSVYTSAIAFTVYMNAVWHGWAIPLFLFLAILRLSLNYLIARGWRIQW SIVPEVSEPVEPPKEDLTVSEKFQLVLDVAQKAQNLFGKMADILEKIKNLFMWVQPEI TQKLYVALWAAFLASCFFPYRLVGLAVGLYAGIKFFLIDFIFKRCPRLRAKYDTPYII WRSLPTDPQLKERSSAAVSRRLQTTSSRSYVPSAPAGLGKEEDAGRFHSTKKGNFHEI FNLTENERPLAVCENGWRCCLINRDRKMPTDYIRNGVLYVTENYLCFESSKSGSSKRN KVIKLVDITDIQKYKVLSVLPGSGMGIAVSTPSTQKPLVFGAMVHRDEAFETILSQYI KITSAAASGGDS (SEQ ID NO: 30) HYAL2 8692 NM_003773 Homo sapiens hyaluronoglucosaminidase 2 (HYAL2), transcript variant 1, mRNA mRNA Sequence TTTCCTCTCAGGGGGCAGCAGGAAGTGAGGAGAAAGGGCTGGGATGGGAGGCGGGAGCGGATGGGAGGGA ATGGGGTTTATCAAGTCCTCGGCGAGCTGCCCAACGGGCAGCAGCTGGCGCAAGTAGCCTAGCTGGAGAG GCTCACCCCAGGAAGGAGGGAGGCCACCGACCTACTGGGCCGACGGACTCCCACACAGTTCCTGAGCTGG TGCCAGGCAGGTGACACCTCCTGCAGCCCCCAGCATGCGGGCAGGCCCAGGCCCCACCGTTACATTGGCC CTGGTGCTGGCGGTGTCATGGGCCATGGAGCTCAAGCCCACAGCACCACCCATCTTCACTGGCCGGCCCT TTGTGGTAGCGTGGGACGTGCCCACACAGGACTGTGGCCCACGCCTCAAGGTGCCACTGGACCTGAATGC CTTTGATGTGCAGGCCTCACCTAATGAGGGTTTTGTGAACCAGAATATTACCATCTTCTACCGCGACCGT CTAGGCCTGTATCCACGCTTCGATTCTGCCGGAAGGTCTGTGCATGGTGGTGTGCCACAGAATGTCAGCC TTTGGGCACACCGGAAGATGCTGCAGAAACGTGTGGAGCACTACATTCGGACACAGGAGTCTGCGGGGCT GGCGGTCATCGACTGGGAGGACTGGCGACCTGTGTGGGTGCGCAACTGGCAGGACAAAGATGTGTATCGC CGGTTATCACGCCAGCTAGTGGCCAGTCGTCACCCTGACTGGCCTCCAGACCGCATAGTCAAACAGGCAC AATATGAGTTTGAGTTCGCAGCACAGCAGTTCATGCTGGAGACACTGCGTTATGTCAAGGCAGTGCGGCC CCGGCACCTCTGGGGCTTCTACCTCTTTCCTGACTGCTACAATCATGATTATGTGCAGAACTGGGAGAGC TACACAGGCCGCTGCCCTGATGTTGAGGTGGCCCGCAATGACCAGCTGGCCTGGCTGTGGGCTGAGAGCA CGGCCCTCTTCCCGTCTGTCTACCTGGACGAGACACTTGCTTCCTCCCGCCATGGCCGCAACTTTGTGAG CTTCCGTGTTCAGGAGGCCCTTCGTGTGGCTCGCACCCACCATGCCAACCATGCACTCCCAGTCTACGTC TTCACACGACCCACCTACAGCCGCAGGCTCACGGGGCTTAGTGAGATGGACCTCATCTCTACCATTGGCG AGAGTGCGGCCCTGGGCGCAGCTGGTGTCATCCTCTGGGGTGACGCGGGGTACACCACAAGCACGGAGAC CTGCCAGTACCTCAAAGATTACCTGACACGGCTGCTGGTCCCCTACGTGGTCAATGTGTCCTGGGCCACC CAATATTGCAGCCGGGCCCAGTGCCATGGCCATGGGCGCTGTGTGCGCCGCAACCCCAGTGCCAGTACCT TCCTGCATCTCAGCACCAACAGTTTCCGCCTAGTGCCTGGCCATGCACCTGGTGAACCCCAGCTGCGACC TGTGGGGGAGCTCAGTTGGGCCGACATTGACCACCTGCAGACACACTTCCGCTGCCAGTGCTACTTGGGC TGGAGTGGTGAGCAATGCCAGTGGGACCATAGGCAGGCAGCTGGAGGTGCCAGCGAGGCCTGGGCTGGGT CCCACCTCACCAGTCTGCTGGCTCTGGCAGCCCTGGCCTTTACCTGGACCTTGTAGGGGTCTCCTGCCTA GCTGCCTAGCAAGCTGGCCTCTACCACAAGGGCTCTCTTAGGCATGTAGGACCCTGCAGGGGGTGGACAA ACTGGAGTCTGGAGTGGGCAGAGCCCCCAGGAAGCCCAGGAGGGCATCCATACCAGCTCGCACCCCCCTG TTCTAAGGGGGAGGGGAAGTCCCTGGGAGGCCCCTTCTCTCCCTGCCAGAGGGGAAGGAGGGTACAGCTG GGCTGGGGAGGACCTGACCCTACTCCCTTGCCCTAGATAGTTTATTATTATTATTATTTTGGGGTCTCTT TTGTAAATTAAACATAAAACAATTGCTTCTCTGCTTGGATTTTGT (SEQ ID NO: 31) Translated protein sequence MRAGPGPTVTLALVLAVSWAMELKPTAPPIFTGRPFVVAWDVPT QDCGPRLKVPLDLNAFDVQASPNEGFVNQNITIFYRDRLGLYPRFDSAGRSVHGGVPQ NVSLWAHRKMLQKRVEHYIRTQESAGLAVIDWEDWRPVWVRNWQDKDVYRRLSRQLVA SRHPDWPPDRIVKQAQYEFEFAAQQFMLETLRYVKAVRPRHLWGFYLFPDCYNHDYVQ NWESYTGRCPDVEVARNDQLAWLWAESTALFPSVYLDETLASSRHGRNFVSFRVQEAL RVARTHHANHALPVYVFTRPTYSRRLTGLSEMDLISTIGESAALGAAGVILWGDAGYT TSTETCQYLKDYLTRLLVPYVVNVSWATQYCSRAQCHGHGRCVRRNPSASTFLHLSTN SFRLVPGHAPGEPQLRPVGELSWADIDHLQTHFRCQCYLGWSGEQCQWDHRQAAGGAS EAWAGSHLTSLLALAALAFTWTL (SEQ ID NO: 32) IL10 3586 NM_000572 Homo sapiens interleukin 10 (IL10), mRNA mRNA Sequence ACACATCAGGGGCTTGCTCTTGCAAAACCAAACCACAAGACAGACTTGCAAAAGAAGGCATGCACAGCTC AGCACTGCTCTGTTGCCTGGTCCTCCTGACTGGGGTGAGGGCCAGCCCAGGCCAGGGCACCCAGTCTGAG AACAGCTGCACCCACTTCCCAGGCAACCTGCCTAACATGCTTCGAGATCTCCGAGATGCCTTCAGCAGAG TGAAGACTTTCTTTCAAATGAAGGATCAGCTGGACAACTTGTTGTTAAAGGAGTCCTTGCTGGAGGACTT TAAGGGTTACCTGGGTTGCCAAGCCTTGTCTGAGATGATCCAGTTTTACCTGGAGGAGGTGATGCCCCAA GCTGAGAACCAAGACCCAGACATCAAGGCGCATGTGAACTCCCTGGGGGAGAACCTGAAGACCCTCAGGC TGAGGCTACGGCGCTGTCATCGATTTCTTCCCTGTGAAAACAAGAGCAAGGCCGTGGAGCAGGTGAAGAA TGCCTTTAATAAGCTCCAAGAGAAAGGCATCTACAAAGCCATGAGTGAGTTTGACATCTTCATCAACTAC ATAGAAGCCTACATGACAATGAAGATACGAAACTGAGACATCAGGGTGGCGACTCTATAGACTCTAGGAC ATAAATTAGAGGTCTCCAAAATCGGATCTGGGGCTCTGGGATAGCTGACCCAGCCCCTTGAGAAACCTTA TTGTACCTCTCTTATAGAATATTTATTACCTCTGATACCTCAACCCCCATTTCTATTTATTTACTGAGCT TCTCTGTGAACGATTTAGAAAGAAGCCCAATATTATAATTTTTTTCAATATTTATTATTTTCACCTGTTT TTAAGCTGTTTCCATAGGGTGACACACTATGGTATTTGAGTGTTTTAAGATAAATTATAAGTTACATAAG GGAGGAAAAAAAATGTTCTTTGGGGAGCCAACAGAAGCTTCCATTCCAAGCCTGACCACGCTTTCTAGCT GTTGAGCTGTTTTCCCTGACCTCCCTCTAATTTATCTTGTCTCTGGGCTTGGGGCTTCCTAACTGCTACA AATACTCTTAGGAAGAGAAACCAGGGAGCCCCTTTGATGATTAATTCACCTTCCAGTGTCTCGGAGGGAT TCCCCTAACCTCATTCCCCAACCACTTCATTCTTGAAAGCTGTGGCCAGCTTGTTATTTATAACAACCTA AATTTGGTTCTAGGCCGGGCGCGGTGGCTCACGCCTGTAATCCCAGCACTTTGGGAGGCTGAGGCGGGTG GATCACTTGAGGTCAGGAGTTCCTAACCAGCCTGGTCAACATGGTGAAACCCCGTCTCTACTAAAAATAC AAAAATTAGCCGGGCATGGTGGCGCGCACCTGTAATCCCAGCTACTTGGGAGGCTGAGGCAAGAGAATTG CTTGAACCCAGGAGATGGAAGTTGCAGTGAGCTGATATCATGCCCCTGTACTCCAGCCTGGGTGACAGAG CAAGACTCTGTCTCAAAAAATAAAAATAAAAATAAATTTGGTTCTAATAGAACTCAGTTTTAACTAGAAT TTATTCAATTCCTCTGGGAATGTTACATTGTTTGTCTGTCTTCATAGCAGATTTTAATTTTGAATAAATA AATGTATCTTATTCACATC (SEQ ID NO: 33) Translated protein sequence MHSSALLCCLVLLTGVRASPGQGTQSENSCTHFPGNLPNMLRDL RDAFSRVKTFFQMKDQLDNLLLKESLLEDFKGYLGCQALSEMIQFYLEEVMPQAENQD PDIKAHVNSLGENLKTLRLRLRRCHRFLPCENKSKAVEQVKNAFNKLQEKGIYKAMSE FDIFINYIEAYMTMKIRN (SEQ ID NO: 34) ITFG3 83986 NM_032039 Homo sapiens integrin alpha FG-GAP repeat containing 3 (ITFG3), mRNA mRNA Sequence AGTGACGCCAGGGGGCGGGGCCAGCGGCGCGGTCGGGTGAGAGGCCGCGGCGGCAGGTCCACCTGGGCTT GCGAAGGCACAGATTCCCCGTCCACAGCTCACGACCAGATGCACCAGCAGGAGTCCACATCGAGGACGTC CTCCGGGCACTCCCACGACCAGTGACCAGGAGTTAAACTTTGGGATGTGCCCGTGATGTTGGACCACAAG GACTTAGAGGCCGAAATCCACCCCTTGAAAAATGAAGAAAGAAAATCGCAGGAAAATCTGGGAAATCCAT CAAAAAATGAGGATAACGTGAAAAGCGCGCCTCCACAGTCCCGGCTCTCCCGGTGCCGAGCGGCGGCGTT TTTTCTTTCATTGTTTCTCTGCCTTTTTGTGGTGTTCGTCGTCTCATTCGTCATCCCGTGTCCAGACCGG CCGGCGTCACAGCGAATGTGGAGGATAGACTACAGTGCCGCTGTTATCTATGACTTTCTGGCTGTGGATG ATATAAACGGGGACAGGATCCAAGATGTTCTTTTTCTTTATAAAAACACCAACAGCAGCAACAATTTCAG CCGATCCTGTGTGGACGAAGGCTTTTCCTCTCCCTGCACCTTTGCAGCTGCTGTGTCGGGGGCCAACGGC AGCACGCTCTGGGAGAGACCTGTGGCCCAAGACGTGGCCCTCGTGGAGTGTGCTGTGCCCCAGCCAAGAG GCAGTGAGGCACCTTCTGCCTGCATCCTGGTGGGCAGACCCAGTTCTTTCATTGCAGTCAACTTGTTCAC AGGGGAAACCCTGTGGAACCACAGCAGCAGCTTCAGCGGGAATGCGTCCATCCTGAGCCCTCTGCTGCAG GTGCCTGATGTGGACGGCGATGGGGCCCCAGACCTGCTGGTTCTCACCCAGGAGCGGGAGGAGGTTAGTG GCCACCTCTACTCCGGCAGCACCGGGCACCAGATTGGCCTCAGAGGCAGCCTTGGTGTGGACGGGGAAAG TGGCTTCCTCCTTCACGTCACCAGGACAGGTGCCCACTACATCCTCTTTCCCTGCGCAAGCTCCCTCTGC GGCTGCTCTGTGAAGGGTCTCTACGAGAAGGTGACCGGGAGCGGCGGCCCGTTCAAGAGTGACCCGCACT GGGAGAGCATGCTCAATGCCACCACCCGCAGGATGCTTTCCCACAGCTCTGGAGCAGTGCGCTACCTGAT GCATGTCCCAGGGAACGCCGGTGCAGATGTGCTTCTTGTGGGCTCAGAGGCCTTCGTGCTGCTGGACGGG CAGGAGCTGACGCCTCGCTGGACACCCAAGGCAGCCCATGTCCTGAGAAAACCCATCTTCGGCCGCTACA AACCAGACACCTTGGCTGTAGCCGTTGAAAACGGAACTGGCACCGACAGACAGATCCTGTTTCTGGACCT TGGCACTGGAGCCGTCCTGTGTAGCCTAGCCCTCCCGAGCCTCCCTGGGGGTCCACTGTCCGCCAGCCTG CCGACCGCAGACCACCGCTCAGCCTTCTTCTTCTGGGGCCTCCACGAGCTGGGGAGCACCAGCGAGACGG AGACCGGGGAGGCCCGGCACAGCCTGTACATGTTCCACCCCACCCTGCCGCGCGTGCTGCTGGAGCTGGC CAATGTCTCTACCCACATTGTCGCCTTTGACGCCGTCCTGTTTGAGCCAAGCCGCCACGCCGCCTACATC CTTCTGACAGGCCCGGCAGACTCAGAGGCACCCGGCCTGGTCTCTGTGATCAAGCACAAGGTGCGGGACC TTGTCCCAAGCAGCAGGGTGGTCCGCCTGGGTGAGGGTGGGCCAGACAGTGACCAAGCCATCAGGGACCG GTTCTCCCGGCTGCGGTACCAGAGTGAGGCGTAGAGGCACGCCAGCCAGAGCCTGTGGAGAGACTCCGCC TGCTGACACTAAACGTCCTGGGAAGTGGGCCCTTCCCTGGGTCTCTGCACTGACTCCCCCACTCCTGACC CTGGTGATGGTCGCCACTGGGCAGCAGCAGCCTTACCAGTCCTCCATGATCACACCCAGGGACCTGCATG GGTGAGGGGACACCCTGGGCCTCTCTCCCGCCCAGCATCCTCCCTGAGTCCCCACACAGGGCCTCACTCT GCACCCCACCAGGGTCCCGCTCACACCAGGCAGCCTTCATAGTGGTCTCCCTGGCCACCTTGGGCAGAGC TGGGTCATGCAGCACCCCATCCTTACCCGGTGCCCTCTCCTTGCCAGCTTCTCCCCAGGCCAGAGCGGCC ATCGCGTAGAAAGAACCAGGGTGTCCCCGGGACAGGCCGTCCCCCACCCCATCCTGTAGAAGTCCATTCC CCTTTTCCCTCCTGTGCTCTGTCCCCCAAGGAGTCATGGAACTCAGGGTACTGGGCCTCAACGGGAACCT GAGACAGCTCCAGCTTCGCAGCCCTTCCCGGAGCTACAGGGGGATCCTCTAGCATGGGGGGTGTGACTTG GTTCCTTTGACCAGGTCCTGTGAGGAAGCCTGGAGCAAGGGTCTCCCCCAGCAGGATGGGTGGGGCCTGC TCTGGAGCTGAGCCCGTGGCCGCTCACAGGTGTCCTTAGTGGTGTTGCAGCTGTCTACTGGCTGCATGTG CTGTGAATATCCCAAGGAACTGGCTGTGGAATGCGTGTTTGGGTCAGTCTGTGCCCTCTCAGTAGACACT GGAGCTGCTCTGTCCCTGAAGAGGCCCCGTGCCCCAGGCATGGCAAGCGCCTGCCTCTCCCCTTCCGGTG CTCACACGCCCACGCCGTGCCACCCGATGCAGGACTCACCTCTGTGCCTTGCTGCTCCTGAGGCCCAAGG GCAGCCATGGTGCTCTGTACTGCTCGGGCCGCCCAGGTCACAGAGCCTGAGCTTCGTAGCCAAAGCAGCC TGATGACCCACCCACCAAGGAAGAAAGCAGAATAAACATTTTTGCACTGCCTGAAAAACCCCGGTGGTCA GGCGTGAGCCTAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 35) Translated protein sequence MLDHKDLEAEIHPLKNEERKSQENLGNPSKNEDNVKSAPPQSRL SRCRAAAFFLSLFLCLFVVFVVSFVIPCPDRPASQRMWRIDYSAAVIYDFLAVDDING DRIQDVLFLYKNTNSSNNFSRSCVDEGFSSPCTFAAAVSGANGSTLWERPVAQDVALV ECAVPQPRGSEAPSACILVGRPSSFIAVNLFTGETLWNHSSSFSGNASILSPLLQVPD VDGDGAPDLLVLTQEREEVSGHLYSGSTGHQIGLRGSLGVDGESGFLLHVTRTGAHYI LFPCASSLCGCSVKGLYEKVTGSGGPFKSDPHWESMLNATTRRMLSHSSGAVRYLMHV PGNAGADVLLVGSEAFVLLDGQELTPRWTPKAAHVLRKPIFGRYKPDTLAVAVENGTG TDRQILFLDLGTGAVLCSLALPSLPGGPLSASLPTADHRSAFFFWGLHELGSTSETET GEARHSLYMFHPTLPRVLLELANVSTHIVAFDAVLFEPSRHAAYILLTGPADSEAPGL VSVIKHKVRDLVPSSRVVRLGEGGPDSDQAIRDRFSRLRYQSEA (SEQ ID NO: 36) JAM3 83700 NM_032801 Homo sapiens junctional adhesion molecule 3 (JAM3), mRNA mRNA Sequence TAGACCTCAGCTTCCTCTGTCACCATGGTGCCGGCTCGGCTGGGCCCGGCGGTCGCCATGGTAACTGGGG CGGGTCGCAGGGTCCTGGCAGGCTGGGCGCATGCGCGCGGGGACTACAAGCCGCGCCGCGCTGCCGCTGG CCCCTCAGCAACCCTCGACATGGCGCTGAGGCGGCCACCGCGACTCCGGCTCTGCGCTCGGCTGCCTGAC TTCTTCCTGCTGCTGCTTTTCAGGGGCTGCCTGATAGGGGCTGTAAATCTCAAATCCAGCAATCGAACCC CAGTGGTACAGGAATTTGAAAGTGTGGAACTGTCTTGCATCATTACGGATTCGCAGACAAGTGACCCCAG GATCGAGTGGAAGAAAATTCAAGATGAACAAACCACATATGTGTTTTTTGACAACAAAATTCAGGGAGAC TTGGCGGGTCGTGCAGAAATACTGGGGAAGACATCCCTGAAGATCTGGAATGTGACACGGAGAGACTCAG CCCTTTATCGCTGTGAGGTCGTTGCTCGAAATGACCGCAAGGAAATTGATGAGATTGTGATCGAGTTAAC TGTGCAAGTGAAGCCAGTGACCCCTGTCTGTAGAGTGCCGAAGGCTGTACCAGTAGGCAAGATGGCAACA CTGCACTGCCAGGAGAGTGAGGGCCACCCCCGGCCTCACTACAGCTGGTATCGCAATGATGTACCACTGC CCACGGATTCCAGAGCCAATCCCAGATTTCGCAATTCTTCTTTCCACTTAAACTCTGAAACAGGCACTTT GGTGTTCACTGCTGTTCACAAGGACGACTCTGGGCAGTACTACTGCATTGCTTCCAATGACGCAGGCTCA GCCAGGTGTGAGGAGCAGGAGATGGAAGTCTATGACCTGAACATTGGCGGAATTATTGGGGGGGTTCTGG TTGTCCTTGCTGTACTGGCCCTGATCACGTTGGGCATCTGCTGTGCATACAGACGTGGCTACTTCATCAA CAATAAACAGGATGGAGAAAGTTACAAGAACCCAGGGAAACCAGATGGAGTTAACTACATCCGCACTGAC GAGGAGGGCGACTTCAGACACAAGTCATCGTTTGTGATCTGAGACCCGCGGTGTGGCTGAGAGCGCACAG AGCGCACGTGCACATACCTCTGCTAGAAACTCCTGTCAAGGCAGCGAGAGCTGATGCACTCGGACAGAGC TAGACACTCATTCAGAAGCTTTTCGTTTTGGCCAAAGTTGACCACTACTCTTCTTACTCTAACAAGCCAC ATGAATAGAAGAATTTTCCTCAAGATGGACCCGGTAAATATAACCACAAGGAAGCGAAACTGGGTGCGTT CACTGAGTTGGGTTCCTAATCTGTTTCTGGCCTGATTCCCGCATGAGTATTAGGGTGATCTTAAAGAGTT TGCTCACGTAAACGCCCGTGCTGGGCCCTGTGAAGCCAGCATGTTCACCACTGGTCGTTCAGCAGCCACG ACAGCACCATGTGAGATGGCGAGGTGGCTGGACAGCACCAGCAGCGCATCCCGGCGGGAACCCAGAAAAG GCTTCTTACACAGCAGCCTTACTTCATCGGCCCACAGACACCACCGCAGTTTCTTCTTAAAGGCTCTGCT GATCGGTGTTGCAGTGTCCATTGTGGAGAAGCTTTTTGGATCAGCATTTTGTAAAAACAACCAAAATCAG GAAGGTAAATTGGTTGCTGGAAGAGGGATCTTGCCTGAGGAACCCTGCTTGTCCAACAGGGTGTCAGGAT TTAAGGAAAACCTTCGTCTTAGGCTAAGTCTGAAATGGTACTGAAATATGCTTTTCTATGGGTCTTGTTT ATTTTATAAAATTTTACATCTAAATTTTTGCTAAGGATGTATTTTGATTATTGAAAAGAAAATTTCTATT TAAACTGTAAATATATTGTCATACAATGTTAAATAACCTATTTTTTTAAAAAAGTTCAACTTAAGGTAGA AGTTCCAAGCTACTAGTGTTAAATTGGAAAATATCAATAATTAAGAGTATTTTACCCAAGGAATCCTCTC ATGGAAGTTTACTGTGATGTTCCTTTTCTCACACAAGTTTTAGCCTTTTTCACAAGGGAACTCATACTGT CTACACATCAGACCATAGTTGCTTAGGAAACCTTTAAAAATTCCAGTTAAGCAATGTTGAAATCAGTTTG CATCTCTTCAAAAGAAACCTCTCAGGTTAGCTTTGAACTGCCTCTTCCTGAGATGACTAGGACAGTCTGT ACCCAGAGGCCACCCAGAAGCCCTCAGATGTACATACACAGATGCCAGTCAGCTCCTGGGGTTGCGCCAG GCGCCCCCGCTCTAGCTCACTGTTGCCTCGCTGTCTGCCAGGAGGCCCTGCCATCCTTGGGCCCTGGCAG TGGCTGTGTCCCAGTGAGCTTTACTCACGTGGCCCTTGCTTCATCCAGCACAGCTCTCAGGTGGGCACTG CAGGGACACTGGTGTCTTCCATGTAGCGTCCCAGCTTTGGGCTCCTGTAACAGACCTCTTTTTGGTTATG GATGGCTCACAAAATAGGGCCCCCAATGCTATTTTTTTTTTTTAAGTTTGTTTAATTATTTGTTAAGATT GTCTAAGGCCAAAGGCAATTGCGAAATCAAGTCTGTCAAGTACAATAACATTTTTAAAAGAAAATGGATC CCACTGTTCCTCTTTGCCACAGAGAAAGCACCCAGACGCCACAGGCTCTGTCGCATTTCAAAACAAACCA TGATGGAGTGGCGGCCAGTCCAGCCTTTTAAAGAACGTCAGGTGGAGCAGCCAGGTGAAAGGCCTGGCGG GGAGGAAAGTGAAACGCCTGAATCAAAAGCAGTTTTCTAATTTTGACTTTAAATTTTTCATCCGCCGGAG ACACTGCTCCCATTTGTGGGGGGACATTAGCAACATCACTCAGAAGCCTGTGTTCTTCAAGAGCAGGTGT TCTCAGCCTCACATGCCCTGCCGTGCTGGACTCAGGACTGAAGTGCTGTAAAGCAAGGAGCTGCTGAGAA GGAGCACTCCACTGTGTGCCTGGAGAATGGCTCTCACTACTCACCTTGTCTTTCAGCTTCCAGTGTCTTG GGTTTTTTATACTTTGACAGCTTTTTTTTAATTGCATACATGAGACTGTGTTGACTTTTTTTAGTTATGT GAAACACTTTGCCGCAGGCCGCCTGGCAGAGGCAGGAAATGCTCCAGCAGTGGCTCAGTGCTCCCTGGTG TCTGCTGCATGGCATCCTGGATGCTTAGCATGCAAGTTCCCTCCATCATTGCCACCTTGGTAGAGAGGGA TGGCTCCCCACCCTCAGCGTTGGGGATTCACGCTCCAGCCTCCTTCTTGGTTGTCATAGTGATAGGGTAG CCTTATTGCCCCCTCTTCTTATACCCTAAAACCTTCTACACTAGTGCCATGGGAACCAGGTCTGAAAAAG TAGAGAGAAGTGAAAGTAGAGTCTGGGAAGTAGCTGCCTATAACTGAGACTAGACGGAAAAGGAATACTC GTGTATTTTAAGATATGAATGTGACTCAAGACTCGAGGCCGATACGAGGCTGTGATTCTGCCTTTGGATG GATGTTGCTGTACACAGATGCTACAGACTTGTACTAACACACCGTAATTTGGCATTTGTTTAACCTCATT TATAAAAGCTTCAAAAAAACCCAAAAAAACCCAAA (SEQ ID NO: 37) Translated protein sequence MVPARLGPAVAMVTGAGRRVLAGWAHARGDYKPRRAAAGPSATL DMALRRPPRLRLCARLPDFFLLLLFRGCLIGAVNLKSSNRTPVVQEFESVELSCIITD SQTSDPRIEWKKIQDEQTTYVFFDNKIQGDLAGRAEILGKTSLKIWNVTRRDSALYRC EVVARNDRKEIDEIVIELTVQVKPVTPVCRVPKAVPVGKMATLHCQESEGHPRPHYSW YRNDVPLPTDSRANPRFRNSSFHLNSETGTLVFTAVHKDDSGQYYCIASNDAGSARCE EQEMEVYDLNIGGIIGGVLVVLAVLALITLGICCAYRRGYFINNKQDGESYKNPGKPD GVNYIRTDEEGDFRHKSSFVI (SEQ ID NO: 38) KLHL17 339451 NM_198317 Homo sapiens kelch-like 17 (Drosophila) (KLHL17), mRNA mRNA Sequence AGTGAGCGACACAGAGCGGGCCGCCACCGCCGAGCAGCCCTCCGGCAGTCTCCGCGTCCGTTAAGCCCGC GGGTCCTCCGCGAATCGGCGGTGGGTCCGGCAGCCGAATGCAGCCCCGCAGCGAGCGCCCGGCCGGCAGG ACGCAGAGCCCGGAGCACGGCAGCCCGGGGCCCGGGCCCGAGGCGCCGCCGCCTCCACCGCCGCAGCCGC CGGCCCCCGAGGCAGAGCGCACGCGGCCCCGGCAGGCTCGGCCCGCAGCCCCCATGGAGGGAGCCGTGCA GCTGCTGAGCCGCGAGGGCCACAGCGTGGCCCACAACTCCAAGCGGCACTACCACGATGCCTTCGTGGCC ATGAGCCGCATGCGCCAGCGCGGCCTCCTGTGCGACATCGTCCTGCACGTGGCTGCCAAGGAGATCCGTG CGCACAAAGTGGTGCTGGCCTCCTGCAGCCCCTACTTCCACGCCATGTTCACAAATGAGATGAGCGAGAG CCGCCAGACCCACGTGACGCTGCACGACATCGACCCTCAGGCCTTGGACCAGCTGGTGCAGTTTGCCTAC ACGGCTGAGATTGTGGTGGGCGAGGGCAATGTGCAGACTCTGCTCCCAGCCGCCAGTCTCCTGCAGCTGA ATGGCGTCCGAGACGCTTGCTGCAAGTTTCTACTGAGTCAGCTCGACCCCTCCAACTGCCTGGGTATCCG GGGCTTTGCCGATGCGCACTCCTGCAGCGACCTGCTCAAGGCCGCCCACAGGTACGTGCTGCAGCACTTC GTGGACGTGGCCAAGACCGAGGAGTTTATGCTGCTGCCCCTGAAACAGGTTCTGGAACTGGTCTCTAGCG ACAGCCTGAACGTGCCTTCAGAGGAGGAGGTCTACCGAGCCGTCCTGAGCTGGGTGAAACACGACGTGGA CGCCCGCAGGCAGCATGTCCCACGGCTCATGAAGTGTGTGCGGCTGCCCTTGCTGAGCCGCGACTTCCTG CTGGGCCACGTGGATGCCGAGAGCCTGGTGAGGCACCACCCTGACTGCAAGGACCTCCTCATCGAGGCCC TGAAGTTCCACCTGCTGCCTGAGCAGAGGGGCGTCCTAGGCACCAGCCGCACACGTCCCCGGCGCTGCGA GGGGGCCGGGCCTGTGCTTTTTGCTGTGGGCGGCGGGAGCCTGTTTGCCATCCACGGAGACTGTGAGGCC TACGACACGCGCACCGACCGCTGGCACGTGGTGGCCTCCATGTCCACGCGCCGGGCCCGGGTGGGAGTGG CTGCGGTGGGGAACCGGCTCTATGCTGTGGGCGGCTATGATGGGACCTCAGACCTGGCTACCGTGGAGTC CTACGACCCCGTGACTAACACGTGGCAGCCGGAGGTGTCCATGGGCACAAGGCGAAGCTGCCTGGGTGTG GCCGCCTTGCATGGACTCCTGTACTCGGCCGGCGGCTATGACGGGGCCTCCTGCCTGAACAGTGCTGAAC GCTACGACCCCCTGACCGGAACGTGGACGTCCGTCGCTGCCATGAGCACCCGGAGGCGCTATGTGCGAGT GGCCACGCTTGATGGGAACCTGTATGCTGTGGGCGGCTACGACAGCTCCTCACACCTGGCCACTGTGGAG AAGTATGAGCCCCAGGTGAACGTGTGGTCGCCCGTGGCGTCCATGCTGAGCCGACGCAGCTCAGCGGGCG TGGCCGTGCTGGAGGGTGCCCTGTACGTGGCAGGGGGCAACGACGGCACCAGCTGCCTCAACTCGGTAGA GAGATACAGTCCAAAGGCTGGAGCCTGGGAAAGCGTGGCGCCCATGAATATCCGCAGGAGCACGCATGAC CTGGTGGCCATGGACGGATGGTTGTACGCCGTGGGGGGTAACGACGGTAGCTCCAGCCTCAACTCCATCG AGAAGTACAACCCGAGGACCAACAAGTGGGTGGCCGCATCCTGCATGTTCACCCGGCGCAGCAGTGTGGG TGTGGCGGTGCTGGAGCTGCTCAATTTCCCGCCGCCATCCTCCCCGACGCTGTCCGTGTCCTCCACCAGC CTCTGACCCACCTACCACCAGAGGCCTGCAGCCTCCCACATGCCTTAAGGGGACCGTGGCCCCCACCAGG GACGTCCTGCGCCATCCGTTCACGTCTCTGCATCCATTCCTTCATGTCTTTATTTAGTTGTTTATTTATT TAGTTATTTATCTTATTTATTGAGGGGTGAGGAGTGCCACGGCTGCCCGTTTACACCTTTAGCGTCTGGT CCTCCTGCGTGTCCTCCCCTCCACTGCCTGCATGGGGGGCGCGGGGAGTGACCAGGCGGGGGCCTCACCG CCCCAGGGCCGTTGCCTGCTCAGACCTTGCAGGCTGTGGAGCAAGAGGCCCTGGGTCTCTCCAAGCAGCT GCAGACCCCAGCTCGAATTTTGCACATGGCGGGGTCCCGGGAAGGGTGGGGAGCAGTTGTCCTTCCTGTC GTCGTCTGCCGTGTGCCATCTTTCCTGGATCTTGTAGTGGGTGCACACGCGTGCACTGGGACCCCACACA GCAATACGAGTCCAACTTAATAAACACATTTCTGGGGTTCCTCAAAAAAAAAAAAAAAAAA (SEQ ID NO: 39) Translated protein sequence MQPRSERPAGRTQSPEHGSPGPGPEAPPPPPPQPPAPEAERTRP RQARPAAPMEGAVQLLSREGHSVAHNSKRHYHDAFVAMSRMRQRGLLCDIVLHVAAKE IRAHKVVLASCSPYFHAMFTNEMSESRQTHVTLHDIDPQALDQLVQFAYTAEIVVGEG NVQTLLPAASLLQLNGVRDACCKFLLSQLDPSNCLGIRGFADAHSCSDLLKAAHRYVL QHFVDVAKTEEFMLLPLKQVLELVSSDSLNVPSEEEVYRAVLSWVKHDVDARRQHVPR LMKCVRLPLLSRDFLLGHVDAESLVRHHPDCKDLLIEALKFHLLPEQRGVLGTSRTRP RRCEGAGPVLFAVGGGSLFAIHGDCEAYDTRTDRWHVVASMSTRRARVGVAAVGNRLY AVGGYDGTSDLATVESYDPVTNTWQPEVSMGTRRSCLGVAALHGLLYSAGGYDGASCL NSAERYDPLTGTWTSVAAMSTRRRYVRVATLDGNLYAVGGYDSSSHLATVEKYEPQVN VWSPVASMLSRRSSAGVAVLEGALYVAGGNDGTSCLNSVERYSPKAGAWESVAPMNIR RSTHDLVAMDGWLYAVGGNDGSSSLNSIEKYNPRTNKWVAASCMFTRRSSVGVAVLEL LNFPPPSSPTLSVSSTSL (SEQ ID NO: 40) KRT24 192666 NM_019016 Homo sapiens keratin 24 (KRT24), mRNA mRNA Sequence ACTCTTCGTCATCACCTCTCCTATTCGCCTGGACAAGCTCATGTTTGCAGGAGCACCATGTCTTGCTCGT CTCGCGCCTCCTCCTCCAGGGCTGGAGGCAGCAGCTCAGCCAGGGTGTCTGCTGGTGGAAGCAGCTTCAG CAGTGGAAGCAGATGTGGTCTGGGGGGCAGCTCGGCCCAGGGCTTCCGAGGAGGAGCCAGCAGCTGCAGC CTGAGTGGGGGGTCTAGCGGTGCTTTTGGGGGCAGCTTTGGAGGGGGCTTTGGTAGCTGCTCAGTAGGGG GTGGTTTTGGGGGAGCTTCAGGCTCTGGGACAGGATTTGGTGGGGGTTCTAGCTTTGGCGGGGTCTCTGG ATTTGGCAGGGGTTCTGGATTCTGTGGGAGTTCTAGATTCAGCAGTGGTGCTACTGGAGGCTTCTACAGC TATGGTGGTGGTATGGGAGGTGGTGTTGGCGATGGGGGGCTTTTCTCTGGAGGGGAAAAGCAAACCATGC AGAACCTCAATGACCGCTTGGCCAATTACCTAGACAAGGTCAGAGCCCTGGAGGAGGCTAACACTGATCT GGAGAACAAAATCAAGGAGTGGTATGACAAATATGGGCCTGGGTCTGGAGACGGTGGATCGGGAAGAGAT TATAGCAAATACTATTCAATAATTGAAGATCTCAGAAACCAGATCATTGCTGCCACTGTTGAAAATGCTG GGATCATTTTGCACATTGACAATGCCAGATTGGCTGCTGATGACTTCAGACTGAAGTATGAGAACGAGCT GTGTCTCCGGCAGAGCGTGGAGGCTGACATCAATGGCCTGCGGAAAGTCCTGGATGACCTGACTATGACC CGCTCTGACCTGGAGATGCAGATTGAGAGTTTCACCGAGGAGCTAGCCTACCTGAGGAAGAACCACGAGG AGGAAATGAAGAATATGCAAGGAAGCTCTGGAGGGGAGGTGACCGTAGAAATGAATGCTGCGCCAGGGAC CGACCTGACCAAATTACTGAATGACATGAGGGCGCAGTACGAGGAGCTGGCTGAGCAAAACCGCCGAGAG GCTGAGGAGCGGTTCAACAAGCAGAGCGCATCACTACAAGCACAAATCTCCACTGATGCTGGGGCAGCCA CTTCTGCCAAGAATGAGATAACAGAACTAAAACGTACCCTGCAAGCCCTGGAAATTGAGCTTCAGTCCCA ACTGGCCATGAAAAGCTCCCTGGAGGGAACCCTGGCTGACACAGAAGCTGGCTACGTGGCTCAGCTGTCA GAAATTCAAACGCAGATCAGTGCCCTGGAGGAGGAGATCTGCCAGATCTGGGGTGAGACTAAATGCCAGA ACGCAGAGTACAAGCAATTGCTGGACATCAAGACACGCCTGGAGGTGGAGATCGAGACCTACCGCCGCCT GCTCGATGGAGAGGGAGGTGGTTCTAGTTTTGCAGAATTTGGTGGTAGAAACTCAGGATCTGTAAACATG GGATCCAGGGATCTGGTATCTGGTGACTCAAGATCTGGAAGCTGTTCTGGTCAAGGACGAGATTCAAGCA AGACTAGAGTGACTAAGACTATCGTAGAGGAGTTGGTGGATGGCAAGGTTGTCTCGTCTCAAGTCAGCAG TATTTCTGAGGTGAAAGTTAAATAAGGAACTTCCAGATCAACAAAAGTGTCTTTCAAAGAAAAAAAAATC AAGAAGGACACAAGCGAAGAAATGGCATCAATCTAGGCATCTTTCTGGATAATTTCAGGAAAAGCTTCAG TCCAGAAATGGATGACTAGCCAACTTTTCTGCATCTTCTTATTTCCTCATTAGAATGCTCTTGAAATAGC TGAATTAACAACTTTGCTTTAATTGTTTCTATGCTTCAATAAATTTACTTTTGCAAGTTAAAAAAAAAAA AAAAAAA (SEQ ID NO: 41) Translated protein sequence MSCSSRASSSRAGGSSSARVSAGGSSFSSGSRCGLGGSSAQGFR GGASSCSLSGGSSGAFGGSFGGGFGSCSVGGGFGGASGSGTGFGGGSSFGGVSGFGRG SGFCGSSRFSSGATGGFYSYGGGMGGGVGDGGLFSGGEKQTMQNLNDRLANYLDKVRA LEEANTDLENKIKEWYDKYGPGSGDGGSGRDYSKYYSIIEDLRNQIIAATVENAGIIL HIDNARLAADDFRLKYENELCLRQSVEADINGLRKVLDDLTMTRSDLEMQIESFTEEL AYLRKNHEEEMKNMQGSSGGEVTVEMNAAPGTDLTKLLNDMRAQYEELAEQNRREAEE RFNKQSASLQAQISTDAGAATSAKNEITELKRTLQALEIELQSQLAMKSSLEGTLADT EAGYVAQLSEIQTQISALEEEICQIWGETKCQNAEYKQLLDIKTRLEVEIETYRRLLD GEGGGSSFAEFGGRNSGSVNMGSRDLVSGDSRSGSCSGQGRDSSKTRVTKTIVEELVD GKVVSSQVSSISEVKVK (SEQ ID NO: 42) MAD2L1BP 9587 NM_014628 Homo sapiens MAD2L1 binding protein (MAD2L1BP), transcript variant 2, mRNA mRNA Sequence ATTCTAACCGCAAGGAGTAGCGGAGGGGAGGTCGTGATGGCGGCGCCGGAGGCGGAGGTTCTGTCCTCAG CCGCAGTCCCTGATTTGGAGTGGTATGAGAAGTCCGAAGAAACTCACGCCTCCCAGATAGAACTACTTGA GACAAGCTCTACGCAGGAACCTCTCAACGCTTCGGAGGCCTTTTGCCCAAGAGACTGCATGGTACCAGTG GTGTTTCCTGGGCCTGTGAGCCAGGAAGGCTGCTGTCAGTTTACTTGTGAACTTCTAAAGCATATCATGT ATCAACGCCAGCAGCTCCCTCTGCCCTATGAACAGCTTAAGCACTTTTACCGAAAACCTTCTCCCCAGGC AGAGGAGATGCTGAAGAAGAAACCTCGGGCCACCACTGAGGTGAGCAGCAGGAAATGCCAACAAGCCCTG GCAGAACTGGAGAGTGTCCTCAGCCACCTGGAGGACTTCTTTGCACGGACACTAGTACCGCGAGTGCTGA TTCTCCTTGGGGGCAATGCCCTAAGCCCCAAGGAGTTCTATGAACTCGACTTGTCTCTGCTGGCCCCCTA CAGCGTGGACCAGAGCCTGAGCACAGCAGCTTGTTTGCGCCGTCTCTTCCGAGCCATATTCATGGCTGAT GCCTTTAGCGAGCTTCAGGCTCCTCCACTCATGGGCACCGTCGTCATGGCACAGGGACACCGCAACTGTG GAGAAGATTGGTTTCGACCCAAGCTCAACTATCGAGTGCCCAGCCGGGGCCATAAACTGACTGTGACCCT GTCATGTGGCAGACCTTCCATCCGAACCACGGCTTGGGAAGACTACATTTGGTTCCAGGCACCAGTGACA TTTAAAGGCTTCCGCGAGTGAATGAGTGCTTCTTAATCCTAAAAACACAATGGCTGAATTATCTTTCTCC ATGTGGCGCTGAATCACCCATCTGGTTTGGAGCTAGAGTTGCTTCCTGGTGAGAGAGGAAGCAACTCTCC TTCTGGTTGTCTGCCTCCCCTCAGATTTCCTGATAGGCTGATGGCATGTGGCTGTGACTGTGACTGTAAT CATTGCTGAACAACATCTCTTTGAATCAAAGGTTGATTTTCCCAGAGGGTGCTGGGTCAGGCATTTCTAT TAGGAGTTGGAAAGCAAAAATGGGTCCATAGACACTCTATGGAGGTGTCCCTTTCTGCTCTTTGCTGTGT CCTTTCAGAATTTTTACCAGGAACATAATGTGGATGTGACTTATGAACTTAAATATAAAATAAATAGATT CTTATTATATTTTCCTGAAAAAA (SEQ ID NO: 43) Translated protein sequence MAAPEAEVLSSAAVPDLEWYEKSEETHASQIELLETSSTQEPLN ASEAFCPRDCMVPVVFPGPVSQEGCCQFTCELLKHIMYQRQQLPLPYEQLKHFYRKPS PQAEEMLKKKPRATTEVSSRKCQQALAELESVLSHLEDFFARTLVPRVLILLGGNALS PKEFYELDLSLLAPYSVDQSLSTAACLRRLFRAIFMADAFSELQAPPLMGTVVMAQGH RNCGEDWFRPKLNYRVPSRGHKLTVTLSCGRPSIRTTAWEDYIWFQAPVTFKGFRE (SEQ ID NO: 44) MANSC1 54682 NM_018050 Homo sapiens MANSC domain containing 1 (MANSC1), mRNA mRNA Sequence AACCACAAAACCCGCCAGGCCGGTGCGGGAGCTGCGGAGCATCCGCTGCGGTCCTCGCCGAGACCCCCGC GCGGATTCGCCGGTCCTTCCCGCGGGCGCGACAGAGCTGTCCTCGCACCTGGATGGCAGCAGGGGCGCCG GGGTCCTCTCGACGCCAGAGAGAAATCTCATCATCTGTGCAGCCTTCTTAAAGCAAACTAAGACCAGAGG GAGGATTATCCTTGACCTTTGAAGACCAAAACTAAACTGAAATTTAAAATGTTCTTCGGGGGAGAAGGGA GCTTGACTTACACTTTGGTAATAATTTGCTTCCTGACACTAAGGCTGTCTGCTAGTCAGAATTGCCTCAA AAAGAGTCTAGAAGATGTTGTCATTGACATCCAGTCATCTCTTTCTAAGGGAATCAGAGGCAATGAGCCC GTATATACTTCAACTCAAGAAGACTGCATTAATTCTTGCTGTTCAACAAAAAACATATCAGGGGACAAAG CATGTAACTTGATGATCTTCGACACTCGAAAAACAGCTAGACAACCCAACTGCTACCTATTTTTCTGTCC CAACGAGGAAGCCTGTCCATTGAAACCAGCAAAAGGACTTATGAGTTACAGGATAATTACAGATTTTCCA TCTTTGACCAGAAATTTGCCAAGCCAAGAGTTACCCCAGGAAGATTCTCTCTTACATGGCCAATTTTCAC AAGCAGTCACTCCCCTAGCCCATCATCACACAGATTATTCAAAGCCCACCGATATCTCATGGAGAGACAC ACTTTCTCAGAAGTTTGGATCCTCAGATCACTTGGAGAAACTATTTAAGATGGATGAAGCAAGTGCCCAG CTCCTTGCTTATAAGGAAAAAGGCCATTCTCAGAGTTCACAATTTTCCTCTGATCAAGAAATAGCTCATC TGCTGCCTGAAAATGTGAGTGCGCTCCCAGCTACGGTGGCAGTTGCTTCTCCACATACCACCTCGGCTAC TCCAAAGCCCGCCACCCTTCTACCCACCAATGCTTCAGTGACACCTTCTGGGACTTCCCAGCCACAGCTG GCCACCACAGCTCCACCTGTAACCACTGTCACTTCTCAGCCTCCCACGACCCTCATTTCTACAGTTTTTA CACGGGCTGCGGCTACACTCCAAGCAATGGCTACAACAGCAGTTCTGACTACCACCTTTCAGGCACCTAC GGACTCGAAAGGCAGCTTAGAAACCATACCGTTTACAGAAATCTCCAACCTAACTTTGAACACAGGGAAT GTGTATAACCCTACTGCACTTTCTATGTCAAATGTGGAGTCTTCCACTATGAATAAAACTGCTTCCTGGG AAGGTAGGGAGGCCAGTCCAGGCAGTTCCTCCCAGGGCAGTGTTCCAGAAAATCAGTACGGCCTTCCATT TGAAAAATGGCTTCTTATCGGGTCCCTGCTCTTTGGTGTCCTGTTCCTGGTGATAGGCCTCGTCCTCCTG GGTAGAATCCTCTCGGAATCACTCCGCAGGAAACGTTACTCAAGACTGGATTATTTGATCAATGGGATCT ATGTGGACATCTAAGGATGGAACTCGGTGTCTCTTAATTCATTTAGTAACCAGAAGCCCAAATGCAATGA GTTTCTGCTGACTTGCTAGTCTTAGCAGGAGGTTGTATTTTGAAGACAGGAAAATGCCCCCTTCTGCTTT CCTTTTTTTTTTTTGGAGACAGAGTCTTGCTTTGTTGCCCAGGCTGGAGTGCAGTAGCACGATCTCGGCT CTCACCGCAACCTCCGTCTCCTGGGTTCAAGCGATTCTCCTGCCTCAGCCTCCTAAGTATCTGGGATTAC AGGCATGTGCCACCACACCTGGGTGATTTTTGTATTTTTAGTAGAGACGGGGTTTCACCATGTTGGTCAG GCTGGTCTCAAACTCCTGACCTAGTGATCCACCCTCCTCGGCCTCCCAAAGTGCTGGGATTACAGGCATG AGCCACCACAGCTGGCCCCCTTCTGTTTTATGTTTGGTTTTTGAGAAGGAATGAAGTGGGAACCAAATTA GGTAATTTTGGGTAATCTGTCTCTAAAATATTAGCTAAAAACAAAGCTCTATGTAAAGTAATAAAGTATA ATTGCCATATAAATTTCAAAATTCAACTGGCTTTTATGCAAAGAAACAGGTTAGGACATCTAGGTTCCAA TTCATTCACATTCTTGGTTCCAGATAAAATCAACTGTTTATATCAATTTCTAATGGATTTGCTTTTCTTT TTATATGGATTCCTTTAAAACTTATTCCAGATGTAGTTCCTTCCAATTAAATATTTG (SEQ ID NO: 45) Translated protein sequence MFFGGEGSLTYTLVIICFLTLRLSASQNCLKKSLEDVVIDIQSS LSKGIRGNEPVYTSTQEDCINSCCSTKNISGDKACNLMIFDTRKTARQPNCYLFFCPN EEACPLKPAKGLMSYRIITDFPSLTRNLPSQELPQEDSLLHGQFSQAVTPLAHHHTDY SKPTDISWRDTLSQKFGSSDHLEKLFKMDEASAQLLAYKEKGHSQSSQFSSDQEIAHL LPENVSALPATVAVASPHTTSATPKPATLLPTNASVTPSGTSQPQLATTAPPVTTVTS QPPTTLISTVFTRAAATLQAMATTAVLTTTFQAPTDSKGSLETIPFTEISNLTLNTGN VYNPTALSMSNVESSTMNKTASWEGREASPGSSSQGSVPENQYGLPFEKWLLIGSLLF GVLFLVIGLVLLGRILSESLRRKRYSRLDYLINGIYVDI (SEQ ID NO: 46) MOBKL1B 55233 NM_018221 Homo sapiens MOB1, Mps One Binder kinase activator-like 1B (yeast) (MOBKL1B), mRNA mRNA Sequence GCGAGGTGGGGTAGGCGGGCAAGGCGGGCGCCGAGGTTTGCAAAGGCTCGCAGCGGCCAGAAACCCGGCT CCGAGCGGCGGCGGCCCGGCTTCCGCTGCCCGTGAGCTAAGGACGGTCCGCTCCCTCTAGCCAGCTCCGA ATCCTGATCCAGGCGGGGGCCAGGGGCCCCTCGCCTCCCCTCTGAGGACCGAAGATGAGCTTCCTCTTCA GCAGCCGCTCTTCTAAAACATTCAAACCAAAGAAGAATATCCCTGAAGGATCTCATCAGTATGAACTCTT AAAACATGCAGAAGCAACTCTAGGAAGTGGGAATCTGAGACAAGCTGTTATGTTGCCTGAGGGAGAGGAT CTCAATGAATGGATTGCTGTGAACACTGTGGATTTCTTTAACCAGATCAACATGTTATATGGAACTATTA CAGAATTCTGCACTGAAGCAAGCTGTCCAGTCATGTCTGCAGGTCCGAGATATGAATATCACTGGGCAGA TGGTACTAATATTAAAAAGCCAATCAAATGTTCTGCACCAAAATACATTGACTATTTGATGACTTGGGTT CAAGATCAGCTTGATGATGAAACTCTTTTTCCTTCTAAGATTGGTGTCCCATTTCCCAAAAACTTTATGT CTGTGGCAAAGACTATTCTAAAGCGTCTGTTCAGGGTTTATGCCCATATTTATCACCAGCACTTTGATTC TGTGATGCAGCTGCAAGAGGAGGCCCACCTCAACACCTCCTTTAAGCACTTTATTTTCTTTGTTCAGGAG TTTAATCTGATTGATAGGCGTGAGCTGGCACCTCTTCAAGAATTAATAGAGAAACTTGGATCAAAAGACA GATAAATGTTTCTTCTAGAACACAGTTACCCCCTTGCTTCATCTATTGCTAGAACTATCTCATTGCTATC TGTTATAGACTAGTGATACAAACTTTAAGAAAACAGGATAAAAAGATACCCATTGCCTGTGTCTACTGAT AAAATTATCCCAAAGGTAGGTTGGTGTGATAGTTTCCGAGTAAGACCTTAAGGACACAGCCAAATCTTAA GTACTGTGTGACCACTCTTGTTGTTATCACATAGTCATACTTGGTTGTAATATGTGATGGTTAACCTGTA GCTTATAAATTTACTTATTATTCTTTTACTCATTTACTCAGTCATTTCTTTACAAGAAAATGATTGAATC TGTTTTAGGTGACAGCACAATGGACATTAAGAATTTCCATCAATAATTTATGAATAAGTTTCCAGAACAA ATTTCCTAATAACACAATCAGATTGGTTTTATTCTTTTATTTTACGAATAAAAAATGTATTTTTCAGTAA AAAAAA (SEQ ID NO: 47) Translated protein sequence MSFLFSSRSSKTFKPKKNIPEGSHQYELLKHAEATLGSGNLRQA VMLPEGEDLNEWIAVNTVDFFNQINMLYGTITEFCTEASCPVMSAGPRYEYHWADGTN IKKPIKCSAPKYIDYLMTWVQDQLDDETLFPSKIGVPFPKNFMSVAKTILKRLFRVYA HIYHQHFDSVMQLQEEAHLNTSFKHFIFFVQEFNLIDRRELAPLQELIEKLGSKDR (SEQ ID NO: 48) NCBP1 4686 NM_002486 Homo sapiens nuclear cap binding protein subunit 1, 80 kDa (NCBP1), mRNA mRNA Sequence ATTGAGAGGCCACCGGGAAACCATTGAGAAGCCCCGGAGGACCGGCCTGAGCGGAGGCGGAGACTAGAGC GGCCGCCGGCACGACCCGCCTTCAGGCGTACGACGACCGCGGCCCGGGGGCTCTGAGTGGCCAAAGCGGC GGCACTTTCTGCGTGGCCCCGGAAGGACATAGAGCGGAAGGCGGGAGAAAGAAGTAGCCGGCAGGCGGAG GCAGCCCGAGGGGGCGGTTGCATGTGTGCCAGACGTTCGTAGCCCACTGAGCTTCCTCACGCCGGCTGTC GCAGCGCCTAGCCCCACCCGGCGGCCTCTCCTGCGCTTCCGGGGCCGTGGCGAGCTAGTGCGCCTGCGTG CCGGCCCATCCGCGCGCCTTGCAGCTGTCCTTGCGTCGGCCAGCGGCCAGACAGTTCCTGCAGCGCTTAC CGCCTGGCCTCTCGGTTCCGCGGCGCACCGGAGGGCAGCATGTCGCGGCGGCGGCACAGCGACGAGAACG ACGGTGGGCAGCCTCACAAAAGGAGAAAGACCTCTGATGCAAATGAAACTGAAGATCATTTGGAATCTTT AATATGTAAAGTAGGAGAAAAGAGTGCCTGCTCTTTGGAGAGCAACCTAGAAGGCTTGGCTGGTGTTTTG GAAGCTGATCTTCCTAACTACAAGAGCAAGATCTTAAGGCTTCTTTGTACAGTTGCACGCCTATTACCTG AGAAGCTGACAATTTATACAACATTAGTTGGACTACTGAATGCCAGGAATTACAATTTTGGTGGAGAATT TGTAGAAGCCATGATTCGTCAACTTAAAGAATCATTGAAAGCAAACAATTATAATGAAGCCGTGTATTTG GTCCGTTTTTTATCTGATCTTGTGAATTGTCATGTGATTGCCGCCCCATCAATGGTTGCTATGTTTGAAA ATTTTGTAAGCGTAACTCAGGAAGAAGATGTACCTCAGGTGCGACGAGATTGGTATGTGTATGCATTTCT GTCATCTTTGCCCTGGGTTGGAAAGGAGTTGTACGAAAAGAAAGATGCAGAGATGGACCGCATCTTTGCC AACACTGAAAGCTATCTTAAAAGACGCCAAAAGACTCATGTACCCATGTTACAGGTATGGACTGCTGATA AACCACATCCACAAGAAGAGTATTTAGATTGCCTGTGGGCCCAGATTCAGAAATTGAAAAAGGATCGCTG GCAGGAACGGCACATCCTAAGACCTTATCTTGCCTTTGACAGCATCCTGTGTGAAGCACTGCAGCACAAT CTGCCTCCTTTTACACCACCTCCTCACACTGAAGATTCAGTGTACCCAATGCCAAGGGTCATCTTCAGAA TGTTTGATTACACAGATGATCCCGAGGGTCCTGTCATGCCAGGGAGTCATTCAGTGGAAAGATTTGTAAT AGAAGAGAATCTTCACTGCATCATTAAGTCCCACTGGAAGGAAAGGAAGACTTGTGCTGCACAGTTAGTG AGCTATCCAGGGAAGAACAAGATCCCCTTGAACTACCACATAGTTGAGGTGATCTTTGCAGAGCTGTTTC AACTTCCAGCACCCCCTCACATTGATGTGATGTACACAACACTCCTCATTGAACTGTGCAAACTTCAACC TGGCTCTCTACCCCAAGTTCTTGCACAGGCAACTGAAATGCTATACATGCGTTTGGACACAATGAACACT ACCTGTGTAGACAGGTTTATTAATTGGTTTTCTCATCATCTAAGTAACTTCCAGTTCCGTTGGAGCTGGG AAGATTGGTCAGATTGTCTTAGTCAAGATCCTGAAAGTCCCAAACCGAAGTTTGTAAGAGAAGTTCTAGA AAAATGTATGAGGTTGTCTTACCATCAGCGTATATTAGATATTGTTCCTCCTACCTTCTCAGCTCTGTGT CCTGCAAACCCAACCTGCATTTACAAGTATGGAGATGAAAGTAGCAATTCTCTTCCTGGACATTCTGTTG CCCTCTGTTTAGCTGTTGCCTTTAAAAGTAAGGCAACCAATGATGAAATCTTCAGCATTCTGAAAGATGT ACCAAATCCTAACCAGGATGATGACGACGATGAAGGATTCAGTTTTAACCCATTGAAAATAGAAGTCTTT GTACAGACTCTGCTACACTTGGCAGCCAAATCATTCAGCCACTCCTTCAGTGCTCTTGCAAAGTTTCATG AAGTCTTCAAAACCCTAGCTGAAAGTGATGAAGGAAAGTTACATGTGCTAAGAGTTATGTTTGAGGTCTG GAGGAACCATCCACAGATGATTGCTGTACTAGTGGATAAGATGATTCGTACACAAATAGTTGATTGTGCT GCCGTAGCAAATTGGATCTTCTCTTCAGAACTATCTCGTGACTTTACCAGATTGTTTGTTTGGGAAATTT TGCACTCTACAATTCGTAAGATGAACAAACATGTCCTGAAGATCCAGAAAGAGCTGGAAGAAGCTAAAGA GAAACTTGCTAGGCAACACAAACGGCGAAGTGATGATGACGACAGAAGCAGTGACAGGAAAGACGGGGTT CTTGAGGAACAAATAGAACGACTTCAGGAAAAAGTGGAATCTGCTCAGAGTGAACAAAAGAATCTTTTCC TCGTTATATTTCAGCGGTTTATCATGATCTTGACCGAGCACCTAGTACGATGCGAAACTGATGGGACCAG TGTATTAACACCATGGTATAAGAACTGTATAGAGAGGCTGCAGCAGATCTTCCTACAGCATCACCAAATA ATCCAGCAGTACATGGTGACCCTGGAGAACCTTCTCTTCACTGCTGAATTAGACCCTCATATCTTGGCCG TGTTCCAGCAGTTCTGTGCCCTGCAGGCCTAAGGGTCATTTTTTCCTCATGTCAAGGTTTTTTTTGATAT CTTAAAATAATTTGTCTTATTTTTTGATGGTTTGAATGCTTGCTTTCTTGTAGTATCCTTTCACTTCTTA AAGGAAACAAAGGGGAAGAGGACAGTGAATGAACATGGCATTACTTTTAATTGCCCTGAAAAGCAAATAC TTCCTAACGGCAGTAATGTGACTATGACCATGATATATTATATATGTGACAGATACAAATTCTCTGTGAT CAGTTTGTTATTTTTTTTCTCCTTAAGGCACAAAATAATTGGTTTGAGGTATGTGAAACACTAGAGGTCA ACCTTACATAGTATATAGAACTGATGGGTTTACCCAGCTACCCAGTAGCATAACTTTTCACAGCTCGGGG ATGAATTAACATGGCTGAAATAAAACTAAAAGTATGGTTTTTAAACTTTGGCATTTCATGATTTATCATC TCACTCTACTCTAAAACTGGTGGTTTCTTACTGAAGGTGTTCTCCATTTGAAATTTTATCTTCAAAGTAT TTTTAAGTAGTATCTTTAAGACATGACTTGTTAGTAATAAAAGTGTTACTAGTTGGAAGAGTAGCTCTCA AATTTGTCTTAATGTAAATCACCTGGGAATCTTTCAAGTTATTTTGAAATTTAAACCACCGTCTGGGGGT GGAACGCAGACATCCTCAGTAATCCTTAAAGTTTCCCCAGGTGATTCCAGGTTTGGTCACCATTATCTTA GAGCATCTACTCACTTCCTCTAGCCTTGGGGTTATTTGTCCAAGGTCTTGTAGTGAGTTACAGAATACTA AAGTGGATGTAGAAGTGGTCAGATTGACTGAAACTATACCCTGAATTAGATGTGAGTTTAGATTTTGTTT ATATGGAACCTGATCCAAAAAACTACGAAGTCCTGAGCTTGTTTCCTGTATAGTACTGATGCTGAAATAA GATGACAGCAGTTTGTAAAATAATACACAAATATGAGGAATTGTCTGACATTCCAAATTTCGAGGATTTT TAGACTTTTTTCATTAAACCTTAGAAAAAAATTACCAGTAATCCTACAACTACTGGTAGTGTTGTTGTGC ATTTGCACAAAATAGGTATAATTTTTTCTTATTACATCCCAAGTTTATGATGCATTAAGCGTTTTGCATA TTTTGATATATTTTTGCTTTGGTTTACCATACATTTTAGTGGCTACAGAATGTAGTCTGCTTAATAAATG GGAATTCCTAGAATGTTTAAATACCATACTATTTAAGACAAAATACAAAATATCCAGAAAAATCCAGGTT GCGTGGCTGGTTAGTAAAGGACTAAAACCCAGGTTCTTGGCTAAATGTTTTCGTTTATACTGTTTATCTT TCCCATTGCTTAAGCACAGCACAAACTATGTAATTATATATAATTACAGTTGACCCTTGAACAACATGGG TTTGAACTGTGTGAGTCTCCTTACACACAGGTTTTCTTCCACCCCTGAGATGGCAAGACCAGCCCCTTGT CTTCCTCAGCCTGCTCAACGTGAAGATGATGAGGATGAAGACCTTTATGATGATCCACTTCTACTTATTA AATAGTAAATATATTTTTTTCTTATGATTTTATTTTCTTTTCTCTAGCTTCATAAGAATATAGCATATGG GCTGGGCGCAGTGGCTCACGCCTGTAATCCCAGCACTTTGGGAGGCTGAGGCGGGCGGATCACAAGGTCA GGAGATTGAGACCATCCTGGCTAACACAGTGAAACCCTGTCTCTACTAAAAACACAAAAACTTAGCCAGG CGTGGTGGTACATGGCTGTAGTCCCAGCTACTTGGGAGGCTGAGACAGGAGAATCGCTTGAACCTGGGAG GTGGAGGTTTCAGTGAGCCAAGATTGTGCCACTGCACTCCAGCCTGGGTGATGGAGCGAGGCTCTGTCTC AAAAAAGAAAAAAAATATATAGCATATAACATACAAAATGAGTTTATCAACTGTTTGTTATTGGTAAGTC AGCAGTGGGCTATTGGTGGTTAAGTTTTGGGGGAGTCAAAAGTTACATGCAAATTTTTTACTGTGCGGGG TGTCAGCATCCCTAACCCCATGTTGTTCAAGGGTCAACTGTAGTTTAAAATGACTCCTGTCTCAAAAAAC CAAAGGATAACCTTTAAGGGATTGGTAACTTTGACTCAAAACTGCTTTGTAATCTTTTCACAATGTACTG AAAAGTGTGGCTAGTTATGTTTGATCCACATTCTAGAGAAATTTGTAGGTTTTAATTTCTTTTCTCTTGG TCCTCTCTTCATGTATAATGGTTGCTTTTAACAGCTGTTCGCTGATGTGGTCCTGCTCTGTCCCAGTCTA GCAGCTTTAGTGTATGGAAAAATTGAACTAGGAATTGAGTTTTGAAGAAATAAAGGTGTAAGAGCAAACA TTCAACAGTTGCTGTCCCCAGTAATGAAGTTCATACAGACAAAAGATGGCATGTCACTGTACATCATACC TTGCAATAAATATTCTGTTAAATTGTGCTGGTGCAATTTAACATGCTTTTGTCAAAGTAAA (SEQ ID NO: 49) Translated protein sequence MSRRRHSDENDGGQPHKRRKTSDANETEDHLESLICKVGEKSAC SLESNLEGLAGVLEADLPNYKSKILRLLCTVARLLPEKLTIYTTLVGLLNARNYNFGG EFVEAMIRQLKESLKANNYNEAVYLVRFLSDLVNCHVIAAPSMVAMFENFVSVTQEED VPQVRRDWYVYAFLSSLPWVGKELYEKKDAEMDRIFANTESYLKRRQKTHVPMLQVWT ADKPHPQEEYLDCLWAQIQKLKKDRWQERHILRPYLAFDSILCEALQHNLPPFTPPPH TEDSVYPMPRVIFRMFDYTDDPEGPVMPGSHSVERFVIEENLHCIIKSHWKERKTCAA QLVSYPGKNKIPLNYHIVEVIFAELFQLPAPPHIDVMYTTLLIELCKLQPGSLPQVLA QATEMLYMRLDTMNTTCVDRFINWFSHHLSNFQFRWSWEDWSDCLSQDPESPKPKFVR EVLEKCMRLSYHQRILDIVPPTFSALCPANPTCIYKYGDESSNSLPGHSVALCLAVAF KSKATNDEIFSILKDVPNPNQDDDDDEGFSFNPLKIEVFVQTLLHLAAKSFSHSFSAL AKFHEVFKTLAESDEGKLHVLRVMFEVWRNHPQMIAVLVDKMIRTQIVDCAAVANWIF SSELSRDFTRLFVWEILHSTIRKMNKHVLKIQKELEEAKEKLARQHKRRSDDDDRSSD RKDGVLEEQIERLQEKVESAQSEQKNLFLVIFQRFIMILTEHLVRCETDGTSVLTPWY KNCIERLQQIFLQHHQIIQQYMVTLENLLFTAELDPHILAVFQQFCALQA (SEQ ID NO: 50) NMU 10874 NM_006681 Homo sapiens neuromedin U (NMU), mRNA mRNA Sequence AGTCCTGTGTCCGGGCCCCGAGGCACAGCCAGGGCACCAGGTGGAGCACCAGCTACGCGTGGCGCAGCGC AGCGTCCCTAGCACCGAGCCTCCCGCAGCCGCCGAGATGCTGCGAACAGAGAGCTGCCGCCCCAGGTCGC CCGCCGGACAGGTGGCCGCGGCGTCCCCGCTCCTGCTGCTGCTGCTGCTGCTCGCCTGGTGCGCGGGCGC CTGCCGAGGTGCTCCAATATTACCTCAAGGATTACAGCCTGAACAACAGCTACAGTTGTGGAATGAGATA GATGATACTTGTTCGTCTTTTCTGTCCATTGATTCTCAGCCTCAGGCATCCAACGCACTGGAGGAGCTTT GCTTTATGATTATGGGAATGCTACCAAAGCCTCAGGAACAAGATGAAAAAGATAATACTAAAAGGTTCTT ATTTCATTATTCGAAGACACAGAAGTTGGGCAAGTCAAATGTTGTGTCGTCAGTTGTGCATCCGTTGCTG CAGCTCGTTCCTCACCTGCATGAGAGAAGAATGAAGAGATTCAGAGTGGACGAAGAATTCCAAAGTCCCT TTGCAAGTCAAAGTCGAGGATATTTTTTATTCAGGCCACGGAATGGAAGAAGGTCAGCAGGGTTCATTTA AAATGGATGCCAGCTAATTTTCCACAGAGCAATGCTATGGAATACAAAATGTACTGACATTTTGTTTTCT TCTGAAAAAAATCCTTGCTAAATGTACTCTGTTGAAAATCCCTGTGTTGTCAATGTTCTCAGTTGTAACA ATGTTGTAAATGTTCAATTTGTTGAAAATTAAAAAATCTAAAAATAAA (SEQ ID NO: 51) Translated protein sequence MLRTESCRPRSPAGQVAAASPLLLLLLLLAWCAGACRGAPILPQ GLQPEQQLQLWNEIDDTCSSFLSIDSQPQASNALEELCFMIMGMLPKPQEQDEKDNTK RFLFHYSKTQKLGKSNVVSSVVHPLLQLVPHLHERRMKRFRVDEEFQSPFASQSRGYF LFRPRNGRRSAGFI (SEQ ID NO: 52) PAPLN 89932 NM_173462 Homo sapiens papilin, proteoglycan-like sulfated glycoprotein (PAPLN), mRNA mRNA Sequence GCGTTCCTTGCGGCCCGGCCGACCTCGCGGGCTTGGGCCTGGGCGGGCACCGACGGAGCGGCCCTGGCTG CAGCCTCCCGGCGCCAGCGAAGACAGGCTGAGATGCGGCTGCTCCTGCTCGTGCCGCTGCTGCTGGCTCC AGCGCCCGGGTCCTCGGCTCCCAAGGTGAGGCGGCAGAGTGACACCTGGGGACCCTGGAGCCAGTGGAGC CCCTGCAGCCGGACCTGTGGAGGGGGTGTCAGCTTCCGGGAGCGCCCCTGCTACTCCCAGAGGAGAGATG GAGGCTCCAGCTGCGTGGGCCCCGCCCGGAGCCACCGCTCTTGTCGCACGGAGAGCTGCCCCGACGGCGC CCGGGACTTCCGGGCCGAGCAGTGCGCGGAGTTCGACGGAGCGGAGTTCCAGGGGCGGCGGTATCGGTGG CTGCCCTACTACAGCGCCCCAAACAAGTGTGAACTGAACTGCATTCCCAAGGGGGAGAACTTCTACTACA AGCACAGGGAGGCTGTGGTTGATGGGACGCCCTGCGAGCCTGGCAAGAGGGATGTCTGTGTGGATGGCAG CTGCCGGGTTGTCGGCTGTGATCACGAGCTGGACTCGTCCAAGCAGGAGGACAAGTGTCTGCGGTGTGGG GGTGACGGCACGACCTGCTACCCCGTCGCAGGCACCTTTGACGCTAATGACCTCAGCCGAGCTGTGAAGA ATGTTCGTGGGGAATACTACCTCAATGGGCACTGGACCATCGAGGCGGCCCGGGCCCTGCCAGCAGCCAG CACCATCCTGCATTACGAGCGGGGTGCTGAGGGGGACCTGGCCCCTGAGCGACTCCATGCCCGGGGCCCC ACCTCGGAGCCCCTGGTCATCGAGCTCATCAGCCAGGAGCCCAACCCCGGTGTGCACTATGAGTACCACC TGCCCCTGCGCCGCCCCAGCCCCGGCTTCAGCTGGAGCCACGGCTCATGGAGTGACTGCAGCGCGGAGTG TGGCGGAGGTCACCAGTCCCGCCTGGTGTTCTGCACCATCGACCATGAGGCCTACCCCGACCACATGTGC CAGCGCCAGCCACGGCCAGCTGACCGGCGTTCCTGCAATCTTCACCCTTGCCCGGAGACCAAGCGCTGGA AGGCAGGGCCATGGGCACCCTGCTCAGCCTCCTGTGGAGGAGGCTCCCAGTCCCGCTCCGTGTACTGCAT CTCGTCTGACGGGGCCGGCATCCAGGAGGCCGTGGAGGAGGCTGAGTGTGCCGGGCTGCCTGGGAAGCCC CCTGCCATTCAGGCCTGTAACCTGCAGCGCTGTGCAGCCTGGAGCCCGGAGCCCTGGGGAGAGTGTTCTG TCAGTTGTGGCGTTGGCGTCCGGAAGCGGAGCGTTACTTGCCGGGGTGAAAGGGGTTCTTTGCTCCATAC CGCAGCGTGCTCCTTGGAAGACCGGCCACCTCTGACTGAGCCCTGTGTGCATGAGGACTGCCCCCTCCTC AGTGACCAGGCCTGGCATGTTGGCACCTGGGGTCTATGCTCCAAGAGCTGCAGCTCGGGCACTCGGAGGC GACAGGTCATCTGTGCCATTGGGCCGCCCAGCCACTGCGGGAGCCTGCAGCACTCCAAGCCTGTGGATGT GGAGCCTTGTAACACGCAGCCCTGTCATCTCCCCCAGGAGGTCCCCAGCATGCAGGATGTGCACACCCCT GCCAGCAACCCCTGGATGCCGTTGGGCCCTCAGGAGTCCCCTGCCTCAGACTCCAGAGGCCAGTGGTGGG CAGCCCAGGAACACCCCTCAGCCAGGGGTGACCACAGGGGAGAACGAGGTGACCCCAGGGGCGACCAAGG CACCCACCTGTCAGCCCTGGGCCCCGCTCCCTCTCTGCAGCAGCCCCCATACCAGCAACCCCTGCGGTCG GGCTCAGGGCCCCACGACTGCAGACACAGTCCTCACGGGTGCTGCCCCGATGGCCACACGGCATCTCTCG GGCCTCAGTGGCAAGGCTGCCCTGGGGCCCCCTGTCAGCAGAGCAGGTACGGGTGCTGCCCTGACAGGGT ATCTGTCGCTGAGGGGCCCCATCACGCTGGCTGCACAAAGTCGTATGGTGGTGACAGCACCGGGGGCATG CCCAGGTCAAGGGCAGTGGCTTCTACAGTCCACAACACCCACCAGCCCCAGGCCCAGCAGAATGAGCCCA GTGAGTGCCGGGGCTCCCAGTTTGGCTGTTGCTATGACAACGTGGCCACTGCAGCCGGTCCTCTTGGGGA AGGCTGTGTGGGCCAGCCCAGCCATGCCTACCCCGTGCGGTGCCTGCTGCCCAGTGCCCATGGCTCTTGC GCAGACTGGGCTGCCCGCTGGTACTTCGTTGCCTCTGTGGGCCAATGTAACCGCTTCTGGTATGGCGGCT GCCATGGCAATGCCAATAACTTTGCCTCGGAGCAAGAGTGCATGAGCAGCTGCCAGGGATCTCTCCATGG GCCCCGTCGTCCCCAGCCTGGGGCTTCTGGAAGGAGCACCCACACGGATGGTGGCGGCAGCAGTCCTGCA GGCGAGCAGGAACCCAGCCAGCACAGGACAGGGGCCGCGGTGCAGAGAAAGCCCTGGCCTTCTGGTGGTC TCTGGCGGCAAGACCAACAGCCTGGGCCAGGGGAGGCCCCCCACACCCAGGCCTTTGGAGAATGGCCATG GGGGCAGGAGCTTGGGTCCAGGGCCCCTGGACTGGGTGGAGATGCCGGATCACCAGCGCCACCCTTCCAC AGCTCCTCCTACAGGATTAGCTTGGCAGGTGTGGAGCCCTCGTTGGTGCAGGCAGCCCTGGGGCAGTTGG TGCGGCTCTCCTGCTCAGACGACACTGCCCCGGAATCCCAGGCTGCCTGGCAGAAAGATGGCCAGCCCAT CTCCTCTGACAGGCACAGGCTGCAGTTCGACGGATCCCTGATCATCCACCCCCTGCAGGCAGAGGACGCG GGCACCTACAGCTGTGGCAGCACCCGGCCAGGCCGCGACTCCCAGAAGATCCAACTTCGCATCATAGGGG GTGACATGGCCGTGCTGTCTGAGGCTGAGCTGAGCCGCTTCCCTCAGCCCAGGGACCCAGCTCAGGACTT TGGCCAAGCGGGGGCTGCTGGGCCCCTGGGGGCCATCCCCTCTTCACACCCACAGCCTGCAAACAGGCTG CGTTTGGACCAGAACCAGCCCCGGGTGGTGGATGCCAGTCCAGGCCAGCGGATCCGGATGACCTGCCGTG CCGAAGGCTTCCCGCCCCCAGCCATCGAGTGGCAGAGAGATGGGCAGCCTGTCTCTTCTCCCAGACACCA GCTGCAGCCTGATGGCTCCCTGGTCATTAGCCGAGTGGCTGTAGAAGATGGCGGCTTCTACACCTGTGTC GCTTTCAATGGGCAGGACCGAGACCAGCGATGGGTCCAGCTCAGAGTTCTGGGGGAGCTGACAATCTCAG GACTGCCCCCTACTGTGACAGTGCCAGAGGGTGATACGGCCAGGCTATTGTGTGTGGTAGCAGGAGAAAG TGTGAACATCAGGTGGTCCAGGAACGGGCTACCTGTGCAGGCTGATGGCCACCGTGTCCACCAGTCCCCA GATGGCACGCTGCTCATTTACAACTTGCGGGCCAGGGATGAGGGCTCCTACACGTGCAGTGCCTACCAGG GGAGCCAGGCAGTCAGCCGCAGCACCGAGGTGAAGGTGGTCTCACCAGCACCCACCGCCCAGCCCAGGGA CCCTGGCAGGGACTGCGTCGACCAGCCAGAGCTGGCCAACTGTGATTTGATCCTGCAGGCCCAGCTTTGT GGCAATGAGTATTACTCCAGCTTCTGCTGTGCCAGCTGTTCACGTTTCCAGCCTCACGCTCAGCCCATCT GGCAGTAGGGATGAAGGCTAGTTCCAGCCCCAGTCCAAAATAGTTCATAGGGCTAGGGAGAAAGGAAGAT GGACTCTTGGCTTCCTCTCTCTGGCTGGCAAAGGGAGTTATCTTCTGGAATACATTAGCTCTTTCAAAAA CCCACCCAGTGTTTAGCCTCAACGGCAGCCAGTTACCAGCTTCTCTCTGTAGCCTTCAGCAGTGTTTGCA TCTCTGACATAACCACAGGCTGCTGTTTTCAAGAAGAGCAATCTGTTTGGATAAGAAAAACCTTTACTTT ACAGCTTCCCTTTATAATTTGTTACACAGGAATAGTTAAATGCATTTGTTTGTTTGTTTTTTGAGACAGA GTTTCACTCTTGTTGCCCAGGCTGGAGGGCAATGGCGCGATCTCAGCTCACTGCAACCTCCGTCTCCTGG GTTCTTGATTCTCCTGTGTCAGCCTTCTGAGTAGCTAGGATTACAGATGCCTATCACCATGCCTGGGTAA TTTTTGTATTTTTAGTTGAGATGGGGTTTCACCATGTTGGCCAGGCTGGTCTCGAACTTCTGACCTCAGA TGATCTGCCCGCCTCAGCCTCCCAAAGTGCTGGGATTACAGGCATGAGCCACCACGCCCAGCCATCAATG CATTTTTTTTATTTTTTTTTTGAGACAGAGTTTCGCACTTCTTGCCCAGGCTGGAGTACAATGGTGCGAT CTTGGCTCACTGCAACCTCCACCTCCTGGGTTCAAGCGCTTCTCCAGCCTCAGCCTCCTGAGTAGCTGGG ATTACAGGTATGTGCCACCATGCCTGGCTAATTTTGTATTTTTAGTAGAGACGGGGTTTCTCCATGTTGG TCAGACTGGTCTTGAACTCCCGACCTCAGGTAATCCGCCCGCCTCGGCCTCCCAAAATGCTGGGATTAGA GGTGTGAGCCACTGTGCCCAGCCCATCAATGTGTTTTAAAGCTAGCTGTCAGGGTTCCACTTAATTTAAA GCTGGGCAGGGAGATGTGTAATGATTTCAAAGTTAACACCTGTTTGTTTTCTAAAGGGCATGCCAAGTCC TGCTGTATCAGGGAAGTATTCTGTGCTAAAATCAGCGATGGTTCATTGCTCTAGTCTCTCTCACCCTTCT AGGCAGTGCATCAGTCAGCTCTAAATCTGGTGCAGAGGGTTAACAGCATAACCCTTGTTGGCAAAATGGA ATAGATGTTAAGACCTCAAATAGGGATTTGGGATGAAACAGCTGCAGTTAGCACTGTTATCTGAGCATGA AAGAACTGGAAACGCTCCTTACGTCGAGATGTTGGACCTTGAAGCCCTCCTGAGGCCAACATGCAAATCT GGCTGTGACGGTTCATCTGACACCTGTGTAAAGCTGACCAGCCTGCTCTGTACAGTGACAATGAGGAGCC CCTCTCTTCCTTAAGTAGGAATCTGTGAAGCAAAATGTTTGCTGCCAAAGACAAATCAGACTGTCAGTCA TTAAAAACAGCATTAGCAGGATGAGGATAGCAATGGGGAAGGGTTGTGGGCAATGCAGTAACAGGGAAAT GGCTTCAGAAATGGTTTGAGTTGGAAGACAACATTCTTCATCTCTCAGGACTTCTAATTCCTTGATGCTA AAAGAAGAGGCATGGATTCTATGAGCTTCCAAGTCCCTTTCCACTTTAACCTTCTACAAATCTTTCAGAG GACTGCCTAGTAGCAAAGGTTATTCCTGGACACAGGAAAGACGGGCATTACAGGGACCAAAGCTCTGAAA GGTGACTTTTATTACCAACACACTGGCTGGAAAAGGGACAAACCACATCACGGGTGAGTGATACTTCTCA GTCTTCTCTACTCATTCAACAAAGGAAATGTGGGCTGGGGCAGAGGTCTTTTTTCATTTAATACTGGAAA AATATTGAAGAGCATCCATGTTCACTTATGGCTGGTTTTGCTATAGAAATTGGAAAATAAAGGCCACTTT TTTGAAATCCCCAGTTTAATTAAAAAAAAAAAAAAAAAA (SEQ ID NO: 53) Translated protein sequence MRLLLLVPLLLAPAPGSSAPKVRRQSDTWGPWSQWSPCSRTCGG GVSFRERPCYSQRRDGGSSCVGPARSHRSCRTESCPDGARDFRAEQCAEFDGAEFQGR RYRWLPYYSAPNKCELNCIPKGENFYYKHREAVVDGTPCEPGKRDVCVDGSCRVVGCD HELDSSKQEDKCLRCGGDGTTCYPVAGTFDANDLSRAVKNVRGEYYLNGHWTIEAARA LPAASTILHYERGAEGDLAPERLHARGPTSEPLVIELISQEPNPGVHYEYHLPLRRPS PGFSWSHGSWSDCSAECGGGHQSRLVFCTIDHEAYPDHMCQRQPRPADRRSCNLHPCP ETKRWKAGPWAPCSASCGGGSQSRSVYCISSDGAGIQEAVEEAECAGLPGKPPAIQAC NLQRCAAWSPEPWGECSVSCGVGVRKRSVTCRGERGSLLHTAACSLEDRPPLTEPCVH EDCPLLSDQAWHVGTWGLCSKSCSSGTRRRQVICAIGPPSHCGSLQHSKPVDVEPCNT QPCHLPQEVPSMQDVHTPASNPWMPLGPQESPASDSRGQWWAAQEHPSARGDHRGERG DPRGDQGTHLSALGPAPSLQQPPYQQPLRSGSGPHDCRHSPHGCCPDGHTASLGPQWQ GCPGAPCQQSRYGCCPDRVSVAEGPHHAGCTKSYGGDSTGGMPRSRAVASTVHNTHQP QAQQNEPSECRGSQFGCCYDNVATAAGPLGEGCVGQPSHAYPVRCLLPSAHGSCADWA ARWYFVASVGQCNRFWYGGCHGNANNFASEQECMSSCQGSLHGPRRPQPGASGRSTHT DGGGSSPAGEQEPSQHRTGAAVQRKPWPSGGLWRQDQQPGPGEAPHTQAFGEWPWGQE LGSRAPGLGGDAGSPAPPFHSSSYRISLAGVEPSLVQAALGQLVRLSCSDDTAPESQA AWQKDGQPISSDRHRLQFDGSLIIHPLQAEDAGTYSCGSTRPGRDSQKIQLRIIGGDM AVLSEAELSRFPQPRDPAQDFGQAGAAGPLGAIPSSHPQPANRLRLDQNQPRVVDASP GQRIRMTCRAEGFPPPAIEWQRDGQPVSSPRHQLQPDGSLVISRVAVEDGGFYTCVAF NGQDRDQRWVQLRVLGELTISGLPPTVTVPEGDTARLLCVVAGESVNIRWSRNGLPVQ ADGHRVHQSPDGTLLIYNLRARDEGSYTCSAYQGSQAVSRSTEVKVVSPAPTAQPRDP GRDCVDQPELANCDLILQAQLCGNEYYSSFCCASCSRFQPHAQPIWQ (SEQ ID NO: 54) PCDH1 5097 NM_002587 Homo sapiens protocadherin 1 (PCDH1), transcript variant 1, mRNA mRNA Sequence CGCAAAGCCGCCGGGCTGCTGCGCCCAGAGCCAGCCGGAGCCGGAGCCGGAGCCCGAACTGCAGCTCCAG CCCCAGCCGTGCGGAGCCGCAGCCCAGGCCGGGGCCGGCGGCGGCTCATGGACAGCGGGGCGGGCGGCCG GCGCTGCCCGGAGGCGGCCCTCCTGATTCTGGGGCCTCCCAGGATGGAGCACCTGAGGCACAGCCCAGGC CCTGGGGGGCAACGGCTACTGCTGCCCTCCATGCTGCTAGCACTGCTGCTCCTGCTGGCTCCATCCCCAG GCCACGCCACTCGGGTAGTGTACAAGGTGCCGGAGGAACAGCCACCCAACACCCTCATTGGGAGCCTCGC AGCCGACTATGGTTTTCCAGATGTGGGGCACCTGTACAAGCTAGAGGTGGGTGCCCCGTACCTTCGCGTG GATGGCAAGACAGGTGACATTTTCACCACCGAGACCTCCATCGACCGTGAGGGGCTCCGTGAATGCCAGA ACCAGCTCCCTGGTGATCCCTGCATCCTGGAGTTTGAGGTATCTATCACAGACCTCGTGCAGAATGGCAG CCCCCGGCTGCTAGAGGGCCAGATAGAAGTACAAGACATCAATGACAACACACCCAACTTCGCCTCACCA GTCATCACTCTGGCCATCCCTGAGAACACCAACATCGGCTCACTCTTCCCCATCCCGCTGGCTTCAGACC GTGATGCTGGTCCCAACGGTGTGGCATCCTATGAGCTGCAGGCTGGGCCTGAGGCCCAGGAGCTATTTGG GCTGCAGGTGGCAGAGGACCAGGAGGAGAAGCAACCACAGCTCATTGTGATGGGCAACCTGGACCGTGAG CGCTGGGACTCCTATGACCTCACCATCAAGGTGCAGGATGGCGGCAGCCCCCCACGCGCCAGCAGTGCCC TGCTGCGTGTCACCGTGCTTGACACCAATGACAACGCCCCCAAGTTTGAGCGGCCCTCCTATGAGGCCGA ACTATCTGAGAATAGCCCCATAGGCCACTCGGTCATCCAGGTGAAGGCCAATGACTCAGACCAAGGTGCC AATGCAGAAATCGAATACACATTCCACCAGGCGCCCGAAGTTGTGAGGCGTCTTCTTCGACTGGACAGGA ACACTGGACTTATCACTGTTCAGGGCCCGGTGGACCGTGAGGACCTAAGCACCCTGCGCTTCTCAGTGCT TGCTAAGGACCGAGGCACCAACCCCAAGAGTGCCCGTGCCCAGGTGGTTGTGACCGTGAAGGACATGAAT GACAATGCCCCCACCATTGAGATCCGGGGCATAGGGCTAGTGACTCATCAAGATGGGATGGCTAACATCT CAGAGGATGTGGCAGAGGAGACAGCTGTGGCCCTGGTGCAGGTGTCTGACCGAGATGAGGGAGAGAATGC AGCTGTCACCTGTGTGGTGGCAGGTGATGTGCCCTTCCAGCTGCGCCAGGCCAGTGAGACAGGCAGTGAC AGCAAGAAGAAGTATTTCCTGCAGACTACCACCCCGCTAGACTACGAGAAGGTCAAAGACTACACCATTG AGATTGTGGCTGTGGACTCTGGCAACCCCCCACTCTCCAGCACTAACTCCCTCAAGGTGCAGGTGGTGGA CGTCAATGACAACGCACCTGTCTTCACTCAGAGTGTCACTGAGGTCGCCTTCCCGGAAAACAACAAGCCT GGTGAAGTGATTGCTGAGATCACTGCCAGTGATGCTGACTCTGGCTCTAATGCTGAGCTGGTTTACTCTC TGGAGCCTGAGCCGGCTGCTAAGGGCCTCTTCACCATCTCACCCGAGACTGGAGAGATCCAGGTGAAGAC ATCTCTGGATCGGGAACAGCGGGAGAGCTATGAGTTGAAGGTGGTGGCAGCTGACCGGGGCAGTCCTAGC CTCCAGGGCACAGCCACTGTCCTTGTCAATGTGCTGGACTGCAATGACAATGACCCCAAATTTATGCTGA GTGGCTACAACTTCTCAGTGATGGAGAACATGCCAGCACTGAGTCCAGTGGGCATGGTGACTGTCATTGA TGGAGACAAGGGGGAGAATGCCCAGGTGCAGCTCTCAGTGGAGCAGGACAACGGTGACTTTGTTATCCAG AATGGCACAGGCACCATCCTATCCAGCCTGAGCTTTGATCGAGAGCAACAAAGCACCTACACCTTCCAGC TGAAGGCAGTGGATGGTGGCGTCCCACCTCGCTCAGCTTACGTTGGTGTCACCATCAATGTGCTGGACGA GAATGACAACGCACCCTATATCACTGCCCCTTCTAACACCTCTCACAAGCTGCTGACCCCCCAGACACGT CTTGGTGAGACGGTCAGCCAGGTGGCAGCCGAGGACTTTGACTCTGGTGTCAATGCTGAGCTGATCTACA GCATTGCAGGTGGCAACCCTTATGGACTCTTCCAGATTGGGTCACATTCAGGTGCCATCACCCTGGAGAA GGAGATTGAGCGGCGCCACCATGGGCTACACCGCCTGGTGGTGAAGGTCAGTGACCGCGGCAAGCCCCCA CGCTATGGCACAGCCTTGGTCCATCTTTATGTCAATGAGACTCTGGCCAACCGCACGCTGCTGGAGACCC TCCTGGGCCACAGCCTGGACACGCCGCTGGATATTGACATTGCTGGGGATCCAGAATATGAGCGCTCCAA GCAGCGTGGCAACATTCTCTTTGGTGTGGTGGCTGGTGTGGTGGCCGTGGCCTTGCTCATCGCCCTGGCG GTTCTTGTGCGCTACTGCAGACAGCGGGAGGCCAAAAGTGGTTACCAGGCTGGTAAGAAGGAGACCAAGG ACCTGTATGCCCCCAAGCCCAGTGGCAAGGCCTCCAAGGGAAACAAAAGCAAAGGCAAGAAGAGCAAGTC CCCAAAGCCCGTGAAGCCAGTGGAGGACGAGGATGAGGCCGGGCTGCAGAAGTCCCTCAAGTTCAACCTG ATGAGCGATGCCCCTGGGGACAGTCCCCGCATCCACCTGCCCCTCAACTACCCACCAGGCAGCCCTGACC TGGGCCGCCACTATCGCTCTAACTCCCCACTGCCTTCCATCCAGCTGCAGCCCCAGTCACCCTCAGCCTC CAAGAAGCACCAGGTGGTACAGGACCTGCCACCTGCAAACACATTCGTGGGCACCGGGGACACCACGTCC ACGGGCTCTGAGCAGTACTCCGACTACAGCTACCGCACCAACCCCCCCAAATACCCCAGCAAGCAGGTAG GCCAGCCCTTTCAGCTCAGCACACCCCAGCCCCTACCCCACCCCTACCACGGAGCCATCTGGACCGAGGT GTGGGAGTGATGGAGCAGGTTTACTGTGCCTGCCCGTGTTGGGGGCCAGCCTGAGCCAGCAGTGGGAGGT GGGGCCTTAGTGCCTCACCGGGCACACGGATTAGGCTGAGTGAAGATTAAGGGAGGGTGTGCTCTGTGGT CTCCTCCCTGCCCTCTCCCCACTGGGGAGAGACCTGTGATTTGCCAAGTCCCTGGACCCTGGACCAGCTA CTGGGCCTTATGGGTTGGGGGTGGTAGGCAGGTGAGCGTAAGTGGGGAGGGAAATGGGTAAGAAGTCTAC TCCAAACCTAGGTCTCTATGTCAGACCAGACCTAGGTGCTTCTCTAGGAGGGAAACAGGGAGACCTGGGG TCCTGTGGATAACTGAGTGGGGAGTCTGCCAGGGGAGGGCACCTTCCCATTGTGCCTTCTGTGTGTATTG TGCATTAACCTCTTCCTCACCACTAGGCTTCTGGGGCTGGGTCCCACATGCCCTTGACCCTGACAATAAA GTTCTCTATTTTTGGAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA A (SEQ ID NO: 55) Translated protein sequence MDSGAGGRRCPEAALLILGPPRMEHLRHSPGPGGQRLLLPSMLL ALLLLLAPSPGHATRVVYKVPEEQPPNTLIGSLAADYGFPDVGHLYKLEVGAPYLRVD GKTGDIFTTETSIDREGLRECQNQLPGDPCILEFEVSITDLVQNGSPRLLEGQIEVQD INDNTPNFASPVITLAIPENTNIGSLFPIPLASDRDAGPNGVASYELQAGPEAQELFG LQVAEDQEEKQPQLIVMGNLDRERWDSYDLTIKVQDGGSPPRASSALLRVTVLDTNDN APKFERPSYEAELSENSPIGHSVIQVKANDSDQGANAEIEYTFHQAPEVVRRLLRLDR NTGLITVQGPVDREDLSTLRFSVLAKDRGTNPKSARAQVVVTVKDMNDNAPTIEIRGI GLVTHQDGMANISEDVAEETAVALVQVSDRDEGENAAVTCVVAGDVPFQLRQASETGS DSKKKYFLQTTTPLDYEKVKDYTIEIVAVDSGNPPLSSTNSLKVQVVDVNDNAPVFTQ SVTEVAFPENNKPGEVIAEITASDADSGSNAELVYSLEPEPAAKGLFTISPETGEIQV KTSLDREQRESYELKVVAADRGSPSLQGTATVLVNVLDCNDNDPKFMLSGYNFSVMEN MPALSPVGMVTVIDGDKGENAQVQLSVEQDNGDFVIQNGTGTILSSLSFDREQQSTYT FQLKAVDGGVPPRSAYVGVTINVLDENDNAPYITAPSNTSHKLLTPQTRLGETVSQVA AEDFDSGVNAELIYSIAGGNPYGLFQIGSHSGAITLEKEIERRHHGLHRLVVKVSDRG KPPRYGTALVHLYVNETLANRTLLETLLGHSLDTPLDIDIAGDPEYERSKQRGNILFG VVAGVVAVALLIALAVLVRYCRQREAKSGYQAGKKETKDLYAPKPSGKASKGNKSKGK KSKSPKPVKPVEDEDEAGLQKSLKFNLMSDAPGDSPRIHLPLNYPPGSPDLGRHYRSN SPLPSIQLQPQSPSASKKHQVVQDLPPANTFVGTGDTTSTGSEQYSDYSYRTNPPKYP SKQVGQPFQLSTPQPLPHPYHGAIWTEVWE (SEQ ID NO: 56) PDGFB 5155 NM_002608 Homo sapiens platelet-derived growth factor beta polypeptide (simian sarcoma viral (v-sis) oncogene homolog) (PDGFB), transcript variant 1, mRNA mRNA Sequence CCTGCCTGCCTCCCTGCGCACCCGCAGCCTCCCCCGCTGCCTCCCTAGGGCTCCCCTCCGGCCGCCAGCG CCCATTTTTCATTCCCTAGATAGAGATACTTTGCGCGCACACACATACATACGCGCGCAAAAAGGAAAAA AAAAAAAAAAAGCCCACCCTCCAGCCTCGCTGCAAAGAGAAAACCGGAGCAGCCGCAGCTCGCAGCTCGC AGCTCGCAGCCCGCAGCCCGCAGAGGACGCCCAGAGCGGCGAGCGGGCGGGCAGACGGACCGACGGACTC GCGCCGCGTCCACCTGTCGGCCGGGCCCAGCCGAGCGCGCAGCGGGCACGCCGCGCGCGCGGAGCAGCCG TGCCCGCCGCCCGGGCCCCGCGCCAGGGCGCACACGCTCCCGCCCCCCTACCCGGCCCGGGCGGGAGTTT GCACCTCTCCCTGCCCGGGTGCTCGAGCTGCCGTTGCAAAGCCAACTTTGGAAAAAGTTTTTTGGGGGAG ACTTGGGCCTTGAGGTGCCCAGCTCCGCGCTTTCCGATTTTGGGGGCCTTTCCAGAAAATGTTGCAAAAA AGCTAAGCCGGCGGGCAGAGGAAAACGCCTGTAGCCGGCGAGTGAAGACGAACCATCGACTGCCGTGTTC CTTTTCCTCTTGGAGGTTGGAGTCCCCTGGGCGCCCCCACACGGCTAGACGCCTCGGCTGGTTCGCGACG CAGCCCCCCGGCCGTGGATGCTCACTCGGGCTCGGGATCCGCCCAGGTAGCGGCCTCGGACCCAGGTCCT GCGCCCAGGTCCTCCCCTGCCCCCCAGCGACGGAGCCGGGGCCGGGGGCGGCGGCGCCCGGGGGCCATGC GGGTGAGCCGCGGCTGCAGAGGCCTGAGCGCCTGATCGCCGCGGACCCGAGCCGAGCCCACCCCCCTCCC CAGCCCCCCACCCTGGCCGCGGGGGCGGCGCGCTCGATCTACGCGTCCGGGGCCCCGCGGGGCCGGGCCC GGAGTCGGCATGAATCGCTGCTGGGCGCTCTTCCTGTCTCTCTGCTGCTACCTGCGTCTGGTCAGCGCCG AGGGGGACCCCATTCCCGAGGAGCTTTATGAGATGCTGAGTGACCACTCGATCCGCTCCTTTGATGATCT CCAACGCCTGCTGCACGGAGACCCCGGAGAGGAAGATGGGGCCGAGTTGGACCTGAACATGACCCGCTCC CACTCTGGAGGCGAGCTGGAGAGCTTGGCTCGTGGAAGAAGGAGCCTGGGTTCCCTGACCATTGCTGAGC CGGCCATGATCGCCGAGTGCAAGACGCGCACCGAGGTGTTCGAGATCTCCCGGCGCCTCATAGACCGCAC CAACGCCAACTTCCTGGTGTGGCCGCCCTGTGTGGAGGTGCAGCGCTGCTCCGGCTGCTGCAACAACCGC AACGTGCAGTGCCGCCCCACCCAGGTGCAGCTGCGACCTGTCCAGGTGAGAAAGATCGAGATTGTGCGGA AGAAGCCAATCTTTAAGAAGGCCACGGTGACGCTGGAAGACCACCTGGCATGCAAGTGTGAGACAGTGGC AGCTGCACGGCCTGTGACCCGAAGCCCGGGGGGTTCCCAGGAGCAGCGAGCCAAAACGCCCCAAACTCGG GTGACCATTCGGACGGTGCGAGTCCGCCGGCCCCCCAAGGGCAAGCACCGGAAATTCAAGCACACGCATG ACAAGACGGCACTGAAGGAGACCCTTGGAGCCTAGGGGCATCGGCAGGAGAGTGTGTGGGCAGGGTTATT TAATATGGTATTTGCTGTATTGCCCCCATGGGGTCCTTGGAGTGATAATATTGTTTCCCTCGTCCGTCTG TCTCGATGCCTGATTCGGACGGCCAATGGTGCTTCCCCCACCCCTCCACGTGTCCGTCCACCCTTCCATC AGCGGGTCTCCTCCCAGCGGCCTCCGGCGTCTTGCCCAGCAGCTCAAGAAGAAAAAGAAGGACTGAACTC CATCGCCATCTTCTTCCCTTAACTCCAAGAACTTGGGATAAGAGTGTGAGAGAGACTGATGGGGTCGCTC TTTGGGGGAAACGGGCTCCTTCCCCTGCACCTGGCCTGGGCCACACCTGAGCGCTGTGGACTGTCCTGAG GAGCCCTGAGGACCTCTCAGCATAGCCTGCCTGATCCCTGAACCCCTGGCCAGCTCTGAGGGGAGGCACC TCCAGGCAGGCCAGGCTGCCTCGGACTCCATGGCTAAGACCACAGACGGGCACACAGACTGGAGAAAACC CCTCCCACGGTGCCCAAACACCAGTCACCTCGTCTCCCTGGTGCCTCTGTGCACAGTGGCTTCTTTTCGT TTTCGTTTTGAAGACGTGGACTCCTCTTGGTGGGTGTGGCCAGCACACCAAGTGGCTGGGTGCCCTCTCA GGTGGGTTAGAGATGGAGTTTGCTGTTGAGGTGGCTGTAGATGGTGACCTGGGTATCCCCTGCCTCCTGC CACCCCTTCCTCCCCACACTCCACTCTGATTCACCTCTTCCTCTGGTTCCTTTCATCTCTCTACCTCCAC CCTGCATTTTCCTCTTGTCCTGGCCCTTCAGTCTGCTCCACCAAGGGGCTCTTGAACCCCTTATTAAGGC CCCAGATGATCCCAGTCACTCCTCTCTAGGGCAGAAGACTAGAGGCCAGGGCAGCAAGGGACCTGCTCAT CATATTCCAACCCAGCCACGACTGCCATGTAAGGTTGTGCAGGGTGTGTACTGCACAAGGACATTGTATG CAGGGAGCACTGTTCACATCATAGATAAAGCTGATTTGTATATTTATTATGACAATTTCTGGCAGATGTA GGTAAAGAGGAAAAGGATCCTTTTCCTAATTCACACAAAGACTCCTTGTGGACTGGCTGTGCCCCTGATG CAGCCTGTGGCTTGGAGTGGCCAAATAGGAGGGAGACTGTGGTAGGGGCAGGGAGGCAACACTGCTGTCC ACATGACCTCCATTTCCCAAAGTCCTCTGCTCCAGCAACTGCCCTTCCAGGTGGGTGTGGGACACCTGGG AGAAGGTCTCCAAGGGAGGGTGCAGCCCTCTTGCCCGCACCCCTCCCTGCTTGCACACTTCCCCATCTTT GATCCTTCTGAGCTCCACCTCTGGTGGCTCCTCCTAGGAAACCAGCTCGTGGGCTGGGAATGGGGGAGAG AAGGGAAAAGATCCCCAAGACCCCCTGGGGTGGGATCTGAGCTCCCACCTCCCTTCCCACCTACTGCACT TTCCCCCTTCCCGCCTTCCAAAACCTGCTTCCTTCAGTTTGTAAAGTCGGTGATTATATTTTTGGGGGCT TTCCTTTTATTTTTTAAATGTAAAATTTATTTATATTCCGTATTTAAAGTTGTAAAAAAAAATAACCACA AAACAAAACCAAATGAAAAAAAAAAAAAAAAAA (SEQ ID NO: 57) Translated protein sequence MNRCWALFLSLCCYLRLVSAEGDPIPEELYEMLSDHSIRSFDDL QRLLHGDPGEEDGAELDLNMTRSHSGGELESLARGRRSLGSLTIAEPAMIAECKTRTE VFEISRRLIDRTNANFLVWPPCVEVQRCSGCCNNRNVQCRPTQVQLRPVQVRKIEIVR KKPIFKKATVTLEDHLACKCETVAAARPVTRSPGGSQEQRAKTPQTRVTIRTVRVRRP PKGKHRKFKHTHDKTALKETLGA (SEQ ID NO: 58) PHOSPHO2 493911 NM_001008489 Homo sapiens phosphatase, orphan 2 (PHOSPHO2), mRNA mRNA Sequence AACAAGGGAGGTGCTGCAGTTGGCGGTCGGGCTAGAGAAGAGAGGCGCCTGCGCTTGCGAGCTGGGCTTG TGAGTGGGGCTGCCGAGAGGGCAGGCGTGGGGCGAGGCCAAAGGACTGAACCCGCAGGAGCGTCACGGGC GCCGGGGCGGCTGCCGACGGCGGGACTGGGTTTTCTATCAGATGTTCCACGTAATAATGCTGGAGTTAAG AAGTTTCCATTATTTTGCTCCAAACCAGAAGACTCTGTTCCCTGTATATAGAATAGGAGTAATATTTGAA AACAACTGGCTGATGTTTAAAACTGAAGATTGTCATGATTGTTTATCCTAATCCCAATGCTGAAGTAAGA TTGTCTTGGAAATACTAAGTTGGGGTAATCCAAATCTATTTCTGGAACCATGAAAATTTTGCTAGTTTTT GACTTTGACAATACAATCATAGATGACAATAGTGACACTTGGATTGTACAATGTGCTCCCAACAAAAAGC TTCCTATTGAACTACGTGATTCTTATCGAAAAGGATTTTGGACAGAATTTATGGGCAGAGTCTTTAAGTA TTTGGGAGATAAGGGTGTAAGAGAACATGAAATGAAAAGAGCAGTGACATCATTGCCTTTCACTCCAGGG ATGGTGGAACTCTTCAACTTTATAAGAAAGAATAAGGATAAATTTGACTGCATTATTATTTCAGATTCAA ATTCGGTCTTCATAGATTGGGTTTTAGAAGCTGCCAGTTTTCATGACATATTTGATAAAGTGTTTACAAA TCCAGCAGCTTTTAATAGCAATGGTCATCTCACTGTTGAAAATTATCATACTCATTCTTGCAATAGATGC CCAAAGAATCTTTGCAAAAAGGTAGTTTTGATAGAATTTGTAGATAAACAGTTACAACAGGGAGTGAATT ATACACAAATTGTTTATATTGGTGATGGTGGAAATGATGTCTGTCCAGTCACCTTTTTAAAGAATGATGA TGTTGCCATGCCACGGAAAGGATATACCTTACAGAAAACTCTTTCCAGAATGTCTCAAAATCTTGAGCCT ATGGAATATTCTGTTGTAGTTTGGTCCTCAGGTGTTGATATAATTTCTCATTTACAATTTCTAATAAAGG ATTAATATGTCAGCAAAAAAAAAAAAAAA (SEQ ID NO: 59) Translated protein sequence MKILLVFDFDNTIIDDNSDTWIVQCAPNKKLPIELRDSYRKGFW TEFMGRVFKYLGDKGVREHEMKRAVTSLPFTPGMVELFNFIRKNKDKFDCIIISDSNS VFIDWVLEAASFHDIFDKVFTNPAAFNSNGHLTVENYHTHSCNRCPKNLCKKVVLIEF VDKQLQQGVNYTQIVYIGDGGNDVCPVTFLKNDDVAMPRKGYTLQKTLSRMSQNLEPM EYSVVVWSSGVDIISHLQFLIKD (SEQ ID NO: 60) PSENEN 55851 NM_172341 Homo sapiens presenilin enhancer 2 homolog (C. elegans) (PSENEN), mRNA mRNA Sequence CTCGCCCAAAGAAGACTACAATCTCCAGGGAAACCTGGGGCGTCTCGCGCAAACGTCCATAACTGAAAGT AGCTAAGGCACCCCAGCCGGAGGAAGTGAGCTCTCCTGGGGCGTGGTTGTTCGTGATCCTTGCATCTGTT ACTTAGGGTCAAGGCTTGGGTCTTGCCCCGCAGACCCTTGGGACGACCCGGCCCCAGCGCAGCTATGAAC CTGGAGCGAGTGTCCAATGAGGAGAAATTGAACCTGTGCCGGAAGTACTACCTGGGGGGGTTTGCTTTCC TGCCTTTTCTCTGGTTGGTCAACATCTTCTGGTTCTTCCGAGAGGCCTTCCTTGTCCCAGCCTACACAGA ACAGAGCCAAATCAAAGGCTATGTCTGGCGCTCAGCTGTGGGCTTCCTCTTCTGGGTGATAGTGCTCACC TCCTGGATCACCATCTTCCAGATCTACCGGCCCCGCTGGGGTGCCCTTGGGGACTACCTCTCCTTCACCA TACCCCTGGGCACCCCCTGACAACTTCTGCACATACTGGGGCCCTGCTTATTCTCCCAGGACAGGCTCCT TAAAGCAGAGGAGCCTGTCCTGGGAGCCCCTTCTCAAACTCCTAAGACTTGTTTTCATGTCCCACGTTCT CTGCTGACATCCCCCAATAAAGGACCCTAACTTTCAAAAAAAAAAAAA (SEQ ID NO: 61) Translated protein sequence MNLERVSNEEKLNLCRKYYLGGFAFLPFLWLVNIFWFFREAFLV PAYTEQSQIKGYVWRSAVGFLFWVIVLTSWITIFQIYRPRWGALGDYLSFTIPLGTP (SEQ ID NO: 62) SATB1 6304 NM_002971 Homo sapiens SATB homeobox 1 (SATB1), transcript variant 1, mRNA mRNA Sequence TTTCTCGCTCGCTCCCGTTCCCCGGACGCGGCGGATGAGCCGGCCCCGCTGGGGAAGGCTCCGGGCGGCG GCGGGCGGCCGGGAGGAGGCTGCGTGCTCGGGGCTGGGGCTGCGAGCGGGGTGATTTTGTATTAAAATGA GGAGGAGGAAGAAGAGGCACCCACAGCGGCAGCGGCGGCGGCGGCGGCAGCAGCAGCAGGAGCAGCGGCG GAGAGGGCTGCAGCCCGGGCGGACGCGCGGAGCCGAGCGGGGCACGGCGGCGGCAGCGACAGCGGCCGGG ATGAGTCAACTAATAATTTAATGGGGGCAGAGACGGCAGCGAGGGGTAGAGCTAGCGAGGGAGAGAGCGA GAGAAGCAGCCCCGTCCGGGGACTCGCGCTCACACTCACGCACACACACAAACACACACACACCTCTCCC TGTGCCACCCAGCAACACCCGGCCTCGTCACAACAACAACAGCCGCGGCCGCCCTCTATCCTGCCCGGGG GCCCAGCCGAAAGCCAGGGCGACTCTAGAGGACGCTGCCCGCCCCCCTCTTTCATTTCGGGAAACTCCTG ATCAGTTTTGTCGGGGTTTCTGGGTTTCTTTTCCCCCAAAGTCCTAGTGCCATTGTGGTGCTCGTTGTTT ACCTCGGACTCTGGACGAGTGAGAGCTTGGCGACTTTTTGGGGGGAGGGGGCGGGGAGTTTGTCGCTGCC TAGGCGGTGGAGGTGGCTGGGGGTGCCTTCTGATCTTCCTCCTCCTCCCCCTCCCCCCGAACCTCTTCTC TCCTCACTTGCTGGGACCCCAGACGCTCACAGCCCCGCGTCAATGGGCAGGGAGAGGGTCCTTGCGGCTG TTGTCAGCGAGGGCAGAATCAAAAGTGGCATTTTAGTGCCTTTCCGGGGCTTTTCTCGCGACCCCCTGCC CCCCACCCTCGCTGTCCCCCGCTAGATGCCCTCGTTGGGGGTGCGAGGCTGTGGGGAAAAGTTTAAGGTT TGTTAATATTAGTCGCGATTGTTGGCGAGGGGGGTGGGGGTGATTGGAAGGGAGGCGAGGTGGCCTTCCC AATGCGCGTTATTCGGGGTTATTGAAGAATAATATTGCAAGTGACAGCCAGAAGTAGACTTTCTGTCCTC ACACCGAAGAACCCGAGTGAGCAGGAGGGAGGGAGAGACGCGAAGAGACCTTTTTTCCTTTTTGGAGACC TTGTCCGCAGTGATTTTTTTTTTTTTAAGAGAATCCTCAGTCACCACGTCGTTTCCCCAGCACCATCACA GTGTACAGCTCATAACGGGTTTTGCTTTGTTTTTACGATTTCCCCCCAACGAATCACTTGTCAGATCAAT TTTATCTTCTTCCTCCTCCCTGCTTCCCACTCTCCCCTCCTCCCCATCGCAAACCCTGTTCTCTGAGGTT AGACATTTTACAAACCCCTATATGTTGGTTTTCGAATTGTGATTTTTTTTTTAAACCCCTTTCTCATGGC TACTCTTCTAGACGTTTATTTCTGCCCTTCCCCCGCTTAGGGGGGCGGGGGTAGGGGAAAGGAAAATAAT ACAATTTCAGGGGAAGTCGCCTTCAGGTCTGCTGCTTTTTTATTTTTTTTTTTTTAATTAAAAAAAAAAA GGACATAGAAAACATCAGTCTTGAACTTCTCTTCAAGAACCCGGGCTGCAAAGGAAATCTCCTTTGTTTT TGTTATTTATGTGCTGTCAAGTTTTGAAGTGGTGATCTTTAGACAGTGACTGAGTATGGATCATTTGAAC GAGGCAACTCAGGGGAAAGAACATTCAGAAATGTCTAACAATGTGAGTGATCCGAAGGGTCCACCAGCCA AGATTGCCCGCCTGGAGCAGAACGGGAGCCCGCTAGGAAGAGGAAGGCTTGGGAGTACAGGTGCAAAAAT GCAGGGAGTGCCTTTAAAACACTCGGGCCATCTGATGAAAACCAACCTTAGGAAAGGAACCATGCTGCCA GTTTTCTGTGTGGTGGAACATTATGAAAACGCCATTGAATATGATTGCAAGGAGGAGCATGCAGAATTTG TGCTGGTGAGAAAGGATATGCTTTTCAACCAGCTGATCGAAATGGCATTGCTGTCTCTAGGTTATTCACA TAGCTCTGCTGCCCAGGCCAAAGGGCTAATCCAGGTTGGAAAGTGGAATCCAGTTCCACTGTCTTACGTG ACAGATGCCCCTGATGCTACAGTAGCAGATATGCTTCAAGATGTGTATCATGTGGTCACATTGAAAATTC AGTTACACAGTTGCCCCAAACTAGAAGACTTGCCTCCCGAACAATGGTCGCACACCACAGTGAGGAATGC TCTGAAGGACTTACTGAAAGATATGAATCAGAGTTCATTGGCCAAGGAGTGCCCCCTTTCACAGAGTATG ATTTCTTCCATTGTGAACAGTACTTACTATGCAAATGTCTCAGCAGCAAAATGTCAAGAATTTGGAAGGT GGTACAAACATTTCAAGAAGACAAAAGATATGATGGTTGAAATGGATAGTCTTTCTGAGCTATCCCAGCA AGGCGCCAATCATGTCAATTTTGGCCAGCAACCAGTTCCAGGGAACACAGCCGAGCAGCCTCCATCCCCT GCGCAGCTCTCCCATGGCAGCCAGCCCTCTGTCCGGACACCTCTTCCAAACCTGCACCCTGGGCTCGTAT CAACACCTATCAGTCCTCAATTGGTCAACCAGCAGCTGGTGATGGCTCAGCTGCTGAACCAGCAGTATGC AGTGAATAGACTTTTAGCCCAGCAGTCCTTAAACCAACAATACTTGAACCACCCTCCCCCTGTCAGTAGA TCTATGAATAAGCCTTTGGAGCAACAGGTTTCGACCAACACAGAGGTGTCTTCCGAAATCTACCAGTGGG TACGCGATGAACTGAAACGAGCAGGAATCTCCCAGGCGGTATTTGCACGTGTGGCTTTTAACAGAACTCA GGGCTTGCTTTCAGAAATCCTCCGAAAGGAAGAGGACCCCAAGACTGCATCCCAGTCTTTGCTGGTAAAC CTTCGGGCTATGCAGAATTTCTTGCAGTTACCGGAAGCTGAAAGAGACCGAATATACCAGGACGAAAGGG AAAGGAGCTTGAATGCTGCCTCGGCCATGGGTCCTGCCCCCCTCATCAGCACACCACCCAGCCGTCCTCC CCAGGTGAAAACAGCTACTATTGCCACTGAAAGGAATGGGAAACCAGAGAACAATACCATGAACATTAAT GCTTCCATTTATGATGAGATTCAGCAGGAAATGAAGCGTGCTAAAGTGTCTCAAGCACTGTTTGCAAAGG TTGCAGCAACCAAAAGCCAGGGATGGTTGTGCGAGCTGTTACGCTGGAAAGAAGATCCTTCTCCAGAAAA CAGAACCCTGTGGGAGAACCTCTCCATGATCCGAAGGTTCCTCAGTCTTCCTCAGCCAGAACGTGATGCC ATTTATGAACAGGAGAGCAACGCGGTGCATCACCATGGCGACAGGCCGCCCCACATTATCCATGTTCCAG CAGAGCAGATTCAGCAACAGCAGCAGCAACAGCAACAGCAGCAGCAGCAGCAGCAGGCACCGCCGCCTCC ACAGCCACAGCAGCAGCCACAGACAGGCCCTCGGCTCCCCCCACGGCAACCCACGGTGGCCTCTCCAGCA GAGTCAGATGAGGAAAACCGACAGAAGACCCGGCCACGAACAAAAATTTCAGTGGAAGCCTTGGGAATCC TCCAGAGTTTCATACAAGACGTGGGCCTGTACCCTGACGAAGAGGCCATCCAGACTCTGTCTGCCCAGCT CGACCTTCCCAAGTACACCATCATCAAGTTCTTTCAGAACCAGCGGTACTATCTCAAGCACCACGGCAAA CTGAAGGACAATTCCGGTTTAGAGGTCGATGTGGCAGAATATAAAGAAGAGGAGCTGCTGAAGGATTTGG AAGAGAGTGTCCAAGATAAAAATACTAACACCCTTTTTTCAGTGAAACTAGAAGAAGAGCTGTCAGTGGA AGGAAACACAGACATTAATACTGATTTGAAAGACTGAGATAAAAGTATTTGTTTCGTTCAACAGTGCCAC TGGTATTTACTAACAAAATGAAAAGTCCACCTTGTCTTCTCTCAGAAAACCTTTGTTGTTCATTGTTTGG CCAATGAATCTTCAAAAACTTGCACAAACAGAAAAGTTGGAAAAGGATAATACAGACTGCACTAAATGTT TTCCTCTGTTTTACAAACTGCTTGGCAGCCCCAGGTGAAGCATCAAGGATTGTTTGGTATTAAAATTTGT GTTCACGGGATGCACCAAAGTGTGTACCCCGTAAGCATGAAACCAGTGTTTTTTGTTTTTTTTTTAGTTC TTATTCCGGAGCCTCAAACAAGCATTATACCTTCTGTGATTATGATTTCCTCTCCTATAATTATTTCTGT AGCACTCCACACTGATCTTTGGAAACTTGCCCCTTATTTAAAAAAAAAAAAGAAAAAAAAGAGTTTGTTA CTCTATTGTATGTTACAAAAGAACTATAGACTGTGGAATGCAGTTTAAAGATGACATATGCCAACAAATG CCTTGTATTATATGGCACTGCCGTAATTCAAATTTGTTTTTATTTTGGAAATAAAAGTTCACTGTACTTT TTTTTCATTCTCATTGTTACATGATTTTTTAAAAAAAGGAAAAGAAAATGTGAAACACAATTTAGTCCTC ATTATTTATTTGTAGATCCTGCAGCATCATGTTGTAATTAATTTTTTGGAAGTTTCCGTTAAATGTAATA TTGCTTCTCTTGTTACCATACTGATTCTTTTCTATTTATAAATGTATTTTGATGGGCAGTAAAACAAAGT GTCTTAAAAGTTTTAAATAGAGAAAATGTGCTTTACACAGTTGCCTATAAAAAGTGCTCTATGTTATCCA AGCAATTCATACTATAAGCTTCACTCTTATTGTTGTATGCAATTTTTACTATCATGCAAATAAGCTTAGG TAAATAAAACTAATAGATCACCTTAGAAAATTATGCAATTAATGTGAAAATAATTGATGTTTGCAATGTG TCTTCCTTTGGTTTACAATCAATTTTAAAGCTACATCTGTATAAAATTTCTGTATAAAGGTGTATTTCTT TTTTATGAGTTTATGGCTATGAAAACAGCTATTTTGTTACAGCTGGCTGTTTTTATAAGTGTATCACAAT TTTCTTTATGCAGAAATGTTCTGACTAGGAGTGGTTATTGACTGTAACTACACAATTAAAATTGTTTGTA TCGTATGACATGGTAGGGTTTGTCTGCTTATGTGAAGTAACTAAAGGAGTCAAAGGATGGCCCTCTCATT TAGGTGCATGTTAATAACTTGTTATTTCACTGATTTTAAAAAGAGCAATTGACAAGTTACTTGAAACACT GTAAATTTAAATCACAAACACATGCTCATTTTTAAATAGGTATGAAATTTCACAATGAAAATAACCTGTT TGGTTAACATTTTGCTTAATAAGTAGAGATAGGATGGTCAAAAGACTCTCCGACAAAAACAAATCCAGTC TCTAGCAGTTATGTTGTTAGAATGGA (SEQ ID NO: 63) Translated protein sequence MDHLNEATQGKEHSEMSNNVSDPKGPPAKIARLEQNGSPLGRGR LGSTGAKMQGVPLKHSGHLMKTNLRKGTMLPVFCVVEHYENAIEYDCKEEHAEFVLVR KDMLFNQLIEMALLSLGYSHSSAAQAKGLIQVGKWNPVPLSYVTDAPDATVADMLQDV YHVVTLKIQLHSCPKLEDLPPEQWSHTTVRNALKDLLKDMNQSSLAKECPLSQSMISS IVNSTYYANVSAAKCQEFGRWYKHFKKTKDMMVEMDSLSELSQQGANHVNFGQQPVPG NTAEQPPSPAQLSHGSQPSVRTPLPNLHPGLVSTPISPQLVNQQLVMAQLLNQQYAVN RLLAQQSLNQQYLNHPPPVSRSMNKPLEQQVSTNTEVSSEIYQWVRDELKRAGISQAV FARVAFNRTQGLLSEILRKEEDPKTASQSLLVNLRAMQNFLQLPEAERDRIYQDERER SLNAASAMGPAPLISTPPSRPPQVKTATIATERNGKPENNTMNINASIYDEIQQEMKR AKVSQALFAKVAATKSQGWLCELLRWKEDPSPENRTLWENLSMIRRFLSLPQPERDAI YEQESNAVHHHGDRPPHIIHVPAEQIQQQQQQQQQQQQQQQAPPPPQPQQQPQTGPRL PPRQPTVASPAESDEENRQKTRPRTKISVEALGILQSFIQDVGLYPDEEAIQTLSAQL DLPKYTIIKFFQNQRYYLKHHGKLKDNSGLEVDVAEYKEEELLKDLEESVQDKNTNTL FSVKLEEELSVEGNTDINTDLKD (SEQ ID NO: 64) SNX11 29916 NM_013323 Homo sapiens sorting nexin 11 (SNX11), transcript variant 2, mRNA mRNA Sequence CCGGCGTCCCAAGTGAGTGGAGGGGGGATCCCGACTCCAGTCCGGGGCCTTGGCCAGCGGAGCCGCGCTA TTCGGAAGCGGGAATCCCACTCAGAGCCCGGGCCTGTAGGGGCGGGGCGTCCCGGGCACCCGGGATTGGG GCGTCTCCCGTCGTGCACCGGGGCACCGGCGACTCACCCGGAAGGAGAAGCCGTGATCTGGCTATATGGT GGGGCGCGGGCGGTGTCGCTGTGGGGAGCTGGTGCTGTTCTCAGATGTTTCCTTCCAATGGGCTTTTGGT GTAGGATGTCGGAGAACCAAGAACAGGAGGAGGTGATTACAGTGCGTGTTCAGGACCCCCGAGTGCAGAA TGAGGGCTCCTGGAACTCTTATGTGGATTATAAGATATTCCTCCATACCAACAGCAAAGCCTTTACTGCC AAGACTTCCTGTGTGCGGCGCCGCTACCGTGAGTTCGTGTGGCTGAGAAAGCAGCTACAGAGAAATGCTG GTTTGGTGCCTGTTCCTGAACTTCCTGGGAAGTCAACCTTCTTCGGCACCTCAGATGAGTTCATTGAGAA GCGACGACAAGGTCTGCAGCACTTCCTTGAAAAGGTCCTGCAGAGTGTGGTTCTCCTGTCAGACAGCCAG TTGCACCTATTCCTGCAAAGCCAGCTCTCGGTGCCTGAGATAGAAGCCTGTGTCCAGGGCCGAAGTACCA TGACTGTGTCTGATGCCATTCTTCGATATGCTATGTCAAACTGTGGCTGGGCCCAGGAAGAGAGGCAGAG CTCTTCTCACCTGGCTAAAGGAGACCAGCCTAAGAGTTGCTGCTTTCTTCCAAGATCGGGTAGGAGGAGC TCTCCCTCACCGCCTCCCAGTGAAGAAAAGGACCATTTAGAAGTGTGGGCTCCAGTTGTTGACTCTGAGG TTCCTTCCTTGGAAAGTCCCACTCTCCCACCCCTCTCCTCACCATTATGCTGTGATTTTGGAAGACCCAA AGAGGGAACCTCCACTCTTCAGTCTGTGAGGAGGGCTGTGGGAGGAGATCATGCTGTGCCTTTGGACCCT GGTCAGTTAGAAACAGTTTTGGAAAAGTGAGCTCTGGGTTCTGCTCTGAGATGGTCAGAGAAGATGCGGG CCAGGAGACTTACTCAGGTGGGACTGGGCACAGGGCAGGTATGTGGGAGGCTGGGCTGCTTAGTGTCTTC TAGTCACCTCTGCTTGGGCTGATTGACAGAGGTCAGTCATTACAGCCCCTTATGCCTCTTCCATGGGAAC AAATACTGTGCAGATGTTTGTAAGTTAAACATAAGACACAGGGGCTGTTGCTTTTGAACAGAACCCTATA TTACTCTCCTGGGATCTGAGTTTCTGCAGGTCATTTGTATGTAGGACCAGGAGTATCTCCTCAGGTGACC AGTTTTGGGGACCCGTATGTGGCAAATTCTAAGCTGCCATATTGAACATCATCCCACTGGGAGTGGTTAT GTTGTATCCCCATCTTGGCTGGCTTCAGTTTTTGCTGTAGCCCTAGAGCACTTTGTTTGTGGGAGGCTGG CCTCTTGCCTACCTCCTTGCATGGACAGGGGGATGAATATTTACTTTCCCACCTCCTTGCTTTTTCTTTC ACTGATACCACTGAATGGAACTGGTGCTGTGACTCCTGCTGCTGGGGATTTATGTCCCGAGACCTTAGCC TGGCTGAGTGGAGCCTGAGACCTGCACAACAGCTCATGGTCATGCATGAGAGAGAAGTGGCTGGCCACAG CCAGAGGGAACAGTAACAGCCCAGGGGCCTTTATTTTGGGAAAGGCTGTCCCGGGCTGTTACTGTCTCTT CTGGTTATAAAGCAGACATGTGGCCATCTTTTCCGCAGGGTTAGAGTGGGCTCCTTTCTTTTTGGAATCC TTTTCTTCTCCTTTGGTAGCAGCTCCCTGCCTCCAGGGCTTCCGCCACCAGCGTCTCTGCTGTGTTGCGC AGTGCAGTGGGGTGCAAGGGCTTTGTTTCTGCCTGCCTGAAAGAGAGGGCTCTGGGGATGGAGATGAGAA ACAACACGCTCTCCTTCAGACAATGAGGCATTCTGTCCTCCTGCTGCCATTCTTCATCTCCACTGAGAGC CAGAGCTGGTAGGAGCCGAGTGCCACAGGCATTCTGCATTGCTCTACTCTTAGGTTTGTGTGTGTGATCC TTCCCCTCCCTGTCGCCCACTCCTCCCTCCTCTGGCTATCCTACCCTGTCTGTGGGCTCTTTTACTACCA GCCTATGCTGTGGGACTGTCATGGCATTTAGTTCAGAGTGGAGGGGCTTTGGCCTGAAATAAAATGCAAG TATTT (SEQ ID NO: 65) Translated protein sequence MGFWCRMSENQEQEEVITVRVQDPRVQNEGSWNSYVDYKIFLHT NSKAFTAKTSCVRRRYREFVWLRKQLQRNAGLVPVPELPGKSTFFGTSDEFIEKRRQG LQHFLEKVLQSVVLLSDSQLHLFLQSQLSVPEIEACVQGRSTMTVSDAILRYAMSNCG WAQEERQSSSHLAKGDQPKSCCFLPRSGRRSSPSPPPSEEKDHLEVWAPVVDSEVPSL ESPTLPPLSSPLCCDFGRPKEGTSTLQSVRRAVGGDHAVPLDPGQLETVLEK (SEQ ID NO: 66) 5PTA1 6708 NM_003126 Homo sapiens spectrin, alpha, erythrocytic 1 (elliptocytosis 2) (SPTA1), mRNA mRNA Sequence TATGTCTTCTAAAGATAATGTCGATTGTGTATGGCTGATGGGATTCTAGGACCAAGCAAGAGGTTTTTTT TTTTCCCCCACATACTTAACGTTTCTATATTTCTATTTGAATTCGACTGGACAGTTCCATTTGAATTATT TCTCTCTCTCTCTCTCTCTGACACATTTTATCTTGCCAGGTTCTAAACCTTTAGGAAAAATGGAGCAATT TCCAAAGGAAACCGTTGTGGAGAGCAGTGGGCCAAAGGTTTTGGAAACAGCAGAAGAGATCCAGGAGAGG CGTCAGGAAGTGTTGACTCGGTATCAAAGTTTCAAGGAGCGGGTCGCTGAGAGGGGTCAGAAGCTTGAGG ATTCCTATCACTTACAAGTTTTCAAGCGAGATGCAGATGATCTGGGGAAGTGGATCATGGAGAAAGTCAA TATCTTAACCGATAAGAGCTATGAAGACCCAACTAATATACAGGGGAAATATCAGAAGCATCAATCCCTT GAAGCAGAGGTGCAAACAAAATCAAGACTCATGTCTGAACTGGAAAAAACAAGGGAAGAACGATTTACCA TGGGTCATTCTGCCCACGAAGAAACGAAGGCCCATATAGAGGAGCTACGCCACCTGTGGGACCTGCTGTT AGAGCTGACCCTGGAGAAGGGTGACCAGTTGCTGCGGGCCCTGAAGTTCCAGCAGTATGTACAGGAGTGT GCTGACATCTTAGAGTGGATTGGAGACAAGGAGGCTATAGCGACATCAGTGGAGCTAGGTGAAGACTGGG AGCGCACCGAAGTTCTGCATAAGAAATTTGAAGACTTCCAAGTGGAGCTGGTAGCTAAAGAAGGGAGAGT TGTTGAAGTGAACCAATATGCCAATGAGTGTGCCGAGGAAAACCATCCTGACCTACCCTTAATTCAGTCT AAGCAAAATGAGGTGAATGCTGCCTGGGAGCGCCTTCGTGGTTTGGCTCTCCAGAGACAGAAAGCTCTGT CCAATGCTGCAAACTTACAACGATTCAAAAGGGATGTGACTGAAGCCATCCAGTGGATCAAGGAGAAGGA ACCTGTACTCACCTCTGAGGACTATGGCAAAGACCTTGTTGCCTCTGAAGGACTGTTTCACAGTCACAAG GGACTTGAGAGAAATCTTGCTGTCATGAGTGACAAGGTGAAGGAGTTATGTGCTAAAGCAGAGAAGCTGA CACTTTCCCATCCTTCAGATGCACCTCAGATCCAGGAGATGAAAGAAGATCTGGTCTCCAGCTGGGAGCA TATTCGTGCCCTGGCCACCAGCAGATATGAAAAACTGCAGGCTACTTATTGGTACCATCGATTTTCATCT GACTTTGATGAACTCTCAGGCTGGATGAACGAGAAGACTGCTGCGATCAATGCTGATGAGCTGCCAACAG ATGTGGCTGGTGGAGAAGTTCTGCTGGACAGGCATCAGCAGCATAAGCATGAGATTGACTCTTACGATGA CCGATTTCAATCTGCTGATGAGACTGGTCAAGACCTCGTGAATGCCAATCATGAAGCCTCTGATGAAGTT CGGGAAAAGATGGAAATACTTGACAACAACTGGACTGCCCTGCTGGAACTGTGGGACGAGCGTCATCGTC AGTATGAGCAGTGCTTGGACTTTCATCTCTTCTACAGAGACAGTGAGCAAGTGGACAGTTGGATGAGTAG ACAAGAGGCCTTCCTGGAAAACGAGGATCTGGGAAACTCACTGGGCAGTGCAGAAGCCCTTCTTCAGAAG CATGAAGACTTTGAGGAAGCCTTTACTGCCCAGGAAGAGAAGATCATAACTGTAGACAAGACTGCAACCA AATTGATTGGTGATGACCATTATGATTCAGAGAACATCAAGGCTATCCGTGACGGGCTGTTAGCCCGGCG GGATGCCCTACGTGAAAAGGCTGCCACTAGACGTAGATTGCTGAAGGAGTCATTGCTTCTGCAAAAACTG TATGAGGACTCAGATGACCTAAAGAACTGGATCAACAAGAAGAAAAAGTTGGCAGATGATGAAGATTACA AGGACATACAGAACTTGAAGAGCAGGGTTCAAAAGCAGCAAGTCTTTGAAAAGGAGTTGGCAGTTAATAA GACCCAGCTGGAAAACATACAGAAAACTGGCCAAGAGATGATTGAGGGTGGTCACTATGCCTCTGACAAT GTGACCACTCGTCTGAGTGAAGTTGCCAGCCTCTGGGAGGAGTTGCTGGAGGCTACAAAACAGAAAGGGA CCCAGTTGCATGAGGCCAACCAGCAGCTGCAATTTGAAAATAATGCAGAAGATTTGCAGCGCTGGCTGGA GGATGTTGAGTGGCAAGTCACCTCTGAGGATTATGGGAAAGGCCTGGCCGAGGTACAGAATCGACTCAGG AAACACGGCCTCCTGGAGTCGGCTGTGGCTGCTCGTCAGGATCAGGTGGATATCCTTACAGACCTGGCTG CATATTTTGAAGAAATAGGCCATCCTGATTCTAAGGATATAAGGGCAAGGCAAGAGTCCTTGGTATGCCG ATTTGAAGCTCTGAAAGAGCCACTGGCCACCCGAAAGAAGAAGCTCTTAGACCTTCTCCATCTGCAGCTG ATTTGTAGAGACACAGAGGATGAGGAGGCCTGGATCCAAGAGACTGAACCCTCAGCTACTTCCACCTACC TTGGAAAGGACCTGATTGCTTCCAAAAAGCTTCTGAATAGGCATAGAGTCATCCTGGAGAACATTGCCAG CCATGAACCACGCATTCAAGAGATAACAGAAAGGGGAAACAAAATGGTAGAGGAAGGACACTTTGCTGCA GAAGATGTGGCCTCTAGGGTCAAGAGTTTGAACCAGAATATGGAGTCTCTCCGTGCTCGAGCTGCTAGGC GACAAAATGATCTTGAAGCCAATGTCCAGTTCCAGCAGTACCTGGCTGACCTGCATGAAGCAGAAACATG GATCAGAGAGAAGGAACCTATTGTAGATAATACTAACTATGGTGCTGATGAAGAAGCAGCTGGGGCTCTT CTAAAGAAGCATGAGGCCTTTCTATTAGATCTCAATTCATTTGGAGACAGTATGAAAGCTCTGCGGAATC AGGCAAACGCCTGCCAGCAACAACAGGCTGCACCAGTGGAGGGAGTTGCTGGAGAACAAAGGGTCATGGC TTTATATGACTTCCAGGCCCGCAGCCCCCGAGAAGTCACCATGAAGAAAGGTGATGTCTTAACGCTGCTC AGTTCCATCAATAAGGACTGGTGGAAGGTGGAAGCTGCTGATCATCAGGGCATTGTCCCAGCTGTCTATG TCAGAAGACTGGCCCACGATGAGTTCCCGATGCTCCCACAGCGGCGACGAGAAGAGCCAGGAAACATCAC CCAGCGCCAGGAGCAGATTGAGAACCAATACCGCTCCCTCTTGGATCGGGCAGAAGAACGCAGACGTCGT CTATTGCAACGTTATAATGAATTTTTATTGGCCTATGAGGCAGGAGACATGCTGGAATGGATTCAAGAGA AAAAGGCAGAAAACACTGGAGTGGAACTAGATGATGTTTGGGAGCTGCAGAAAAAGTTTGATGAGTTCCA AAAGGATTTGAATACCAATGAGCCTCGGCTAAGGGATATCAACAAGGTAGCTGATGATCTACTATTTGAA GGACTTCTAACACCAGAAGGAGCTCAAATCCGGCAGGAATTGAATTCCCGCTGGGGTTCTTTGCAGAGGC TTGCAGATGAACAGCGGCAGCTGCTGGGCAGTGCCCATGCTGTTGAAGTGTTTCACAGAGAAGCAGATGA CACGAAGGAGCAGATTGAGAAGAAATGCCAGGCCCTCAGTGCTGCAGACCCTGGCTCAGATCTGTTCAGT GTTCAGGCTCTTCAGCGACGGCATGAGGGCTTTGAAAGGGACCTCGTACCCCTGGGAGATAAGGTGACCA TACTGGGGGAGACAGCAGAGCGGCTCAGTGAGTCCCATCCAGATGCCACTGAGGACCTGCAGAGACAGAA AATGGAGCTGAATGAGGCCTGGGAAGACCTGCAGGGGCGTACAAAGGATCGTAAGGAGAGCCTAAATGAG GCCCAGAAATTCTACCTGTTCCTCAGCAAGGCCAGGGATCTGCAGAACTGGATCAGTAGCATTGGTGGCA TGGTATCATCACAGGAGCTGGCCGAAGACTTAACTGGCATAGAGATCTTGCTGGAGAGACATCAGGAGCA CCGTGCTGACATGGAGGCAGAGGCTCCCACCTTCCAGGCCTTAGAGGACTTCAGTGCAGAACTTATCGAC AGTGGGCACCATGCTAGCCCTGAAATTGAAAAAAAGCTTCAAGCTGTCAAGCTAGAGAGAGATGATTTGG AGAAGGCTTGGGAAAAACGCAAGAAGATCCTAGACCAGTGCCTGGAGTTGCAGATGTTCCAGGGGAACTG TGATCAAGTTGAGAGCTGGATGGTGGCACGTGAGAATTCCCTGAGGTCAGATGACAAAAGTTCCTTAGAC AGTCTGGAGGCTTTGATGAAGAAACGGGACGATTTGGACAAAGCAATCACTGCCCAGGAAGGGAAGATCA CTGACCTAGAACATTTTGCTGAGAGCCTCATTGCTGATGAACACTATGCCAAAGAAGAGATTGCTACGCG GCTCCAACGTGTACTAGACAGGTGGAAGGCTCTCAAAGCACAACTGATTGATGAGCGGACAAAGCTTGGA GACTATGCCAACCTAAAACAATTCTACCGAGACCTTGAGGAGCTGGAAGAATGGATCAGTGAGATGCTGC CCACAGCCTGTGATGAATCCTACAAAGACGCCACTAACATTCAGAGGAAATACCTGAAACACCAGACCTT TGCACATGAAGTCGATGGCCGATCTGAGCAGGTGCATGGCGTCATCAACCTGGGGAACTCCCTGATTGAG TGTAGCGCTTGTGATGGCAATGAAGAGGCCATGAAGGAGCAACTGGAACAGCTGAAGGAACATTGGGATC ATCTGCTTGAGAGAACAAATGACAAAGGGAAGAAGCTCAATGAGGCCAGTCGTCAACAGAGGTTCAACAC AAGCATCCGGGACTTTGAGTTCTGGCTCTCAGAGGCAGAGACATTGCTGGCCATGAAAGATCAGGCCAGG GACTTGGCTTCAGCAGGAAACCTACTCAAGAAGCATCAGCTATTGGAGAGAGAGATGTTGGCTCGAGAGG ATGCACTCAAGGACCTGAATACATTGGCTGAAGATTTGCTCTCCAGCGGGACTTTCAACGTTGATCAGAT TGTGAAGAAAAAAGATAATGTCAACAAGCGTTTCCTGAATGTCCAAGAATTGGCAGCTGCACACCACGAA AAATTGAAAGAGGCCTATGCCTTGTTCCAGTTCTTCCAGGATCTAGATGATGAGGAATCCTGGATAGAGG AGAAGTTGATACGAGTGAGCTCCCAGGACTATGGGAGAGATCTTCAGGGGGTTCAGAACTTGCTGAAGAA GCACAAACGCCTAGAGGGGGAGCTGGTGGCCCATGAGCCTGCCATCCAGAATGTGCTGGATATGGCAGAG AAGCTGAAAGACAAGGCTGCTGTGGGGCAAGAGGAGATCCAGTTGCGGCTGGCTCAGTTTGTTGAACACT GGGAGAAGCTCAAAGAGTTGGCCAAGGCCCGAGGACTTAAGTTGGAAGAATCCCTAGAATACTTGCAATT CATGCAGAATGCTGAGGAAGAGGAAGCTTGGATCAATGAAAAGAATGCTTTGGCTGTCCGAGGAGATTGT GGAGATACATTAGCTGCTACTCAGAGCTTGCTAATGAAGCATGAAGCTTTGGAAAATGACTTTGCTGTCC ATGAGACCCGAGTACAAAATGTGTGTGCACAAGGAGAAGACATCCTAAATAAGGTGTTGCAGGAGGAAAG TCAGAACAAAGAGATTTCTTCCAAGATAGAGGCTCTGAATGAAAAGACCCCTTCTCTGGCTAAGGCAATA GCTGCTTGGAAGTTGCAATTGGAAGACGATTATGCCTTTCAGGAATTCAACTGGAAGGCTGATGTGGTAG AGGCTTGGATAGCTGATAAGGAAACAAGCCTAAAGACCAATGGCAATGGTGCAGACCTTGGTGACTTCCT CACTCTTCTGGCAAAACAGGACACTCTGGATGCCAGTCTGCAGAGTTTCCAGCAAGAGAGACTTCCCGAG ATCACTGACCTGAAGGACAAACTGATTTCTGCTCAACACAACCAGTCTAAAGCCATTGAAGAGCGTTATG CCGCTCTGCTGAAGCGCTGGGAACAGTTGCTGGAAGCCTCGGCAGTCCACAGACAGAAATTGCTGGAGAA ACAGCTGCCTCTACAGAAGGCTGAGGACCTGTTCGTGGAATTTGCACATAAGGCTTCAGCTTTGAACAAC TGGTGTGAAAAGATGGAAGAAAACTTGTCAGAGCCTGTGCACTGTGTCTCCCTGAATGAAATTCGGCAGC TGCAGAAAGACCATGAGGACTTCTTGGCCTCCCTGGCTAGGGCTCAAGCAGACTTTAAATGTTTGCTGGA GCTAGACCAGCAGATTAAGGCCTTAGGTGTGCCTTCCAGCCCTTATACCTGGTTAACAGTGGAGGTGCTG GAAAGGACCTGGAAGCACCTATCTGACATCATTGAGGAACGGGAGCAGGAGCTGCAAAAGGAAGAGGCAA GACAGGTCAAGAACTTTGAGATGTGTCAGGAGTTTGAACAGAATGCCAGTACCTTCCTTCAATGGATCCT GGAAACCAGGGCTTACTTTCTGGATGGATCATTGCTCAAAGAAACAGGAACTCTGGAATCTCAGCTGGAA GCAAATAAAAGAAAACAGAAGGAGATCCAGGCGATGAAGCGTCAACTAACCAAGATTGTGGACCTGGGGG ACAACTTGGAAGACGCTCTGATCCTTGATATCAAATACAGCACCATTGGATTGGCTCAGCAGTGGGACCA GCTCTACCAGCTTGGGTTGCGGATGCAACACAACCTGGAGCAACAGATCCAGGCCAAGGACATCAAAGGT GTGAGTGAAGAGACTCTAAAGGAATTTAGCACAATCTATAAACACTTTGATGAGAATTTGACAGGGCGCC TGACTCACAAAGAGTTCCGGTCCTGCCTGAGAGGACTCAATTACTACTTGCCCATGGTGGAGGAGGATGA ACATGAGCCCAAGTTTGAGAAGTTCCTGGATGCTGTGGATCCAGGGAGGAAGGGCTATGTCTCACTGGAG GACTATACTGCTTTCCTGATTGACAAGGAGTCAGAAAACATCAAGTCCAGTGATGAAATAGAGAATGCCT TCCAAGCCCTGGCAGAGGGCAAGTCATATATTACCAAAGAAGACATGAAGCAGGCCCTTACCCCAGAGCA AGTGTCATTCTGTGCCACACATATGCAGCAATATATGGACCCACGGGGTCGAAGCCATCTCTCTGGCTAT GACTACGTTGGCTTCACCAATTCCTACTTTGGCAACTAATAAGCAGCTCCTCGTGGATCGTAGAAAATCT TAGTGTCGTGGGAAATTTACTGGGGGGCAAAGAGTACAGGCAAATGTGGAAGATAAAGATGGCCTCGTGT GTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGCTTGTGTTTGTGTGCATATTACATTTATTGTAGGATCTT AAAAAATCTCAAGGGTGGGAGATAGAAAGGTTAATAGAGTTGGAGGAGTGGAAGCTATTTTGTATGCAAC TAGTCACTGCTGAGGGGTGTCAAAGTTTCTATTTTTATTTGTTCTGTTTTGCACGTCTTTATCATTTTGC TTTATTCCGATTATAGAATAAAGTAATTCTTTTTAAAAATATTTTTTGGGGCAAAGTTAAGTAAAATGTT GAGCTTCTATATTTCTGGGAACTGTACTCATATAAGAGTGGGCAGCTAATTTTACTGTAAAGAAGGGCCA TGGTATAGTAGATAAATAAAATCCAAGGCAATTTTCAAACAATTTTTTTAAACTTTGGAATGTGTTTAAA TTTAAATTTGAAAATAAAGATATTTGATTTTCTGGGG (SEQ ID NO: 67) Translated protein sequence MEQFPKETVVESSGPKVLETAEEIQERRQEVLTRYQSFKERVAE RGQKLEDSYHLQVFKRDADDLGKWIMEKVNILTDKSYEDPTNIQGKYQKHQSLEAEVQ TKSRLMSELEKTREERFTMGHSAHEETKAHIEELRHLWDLLLELTLEKGDQLLRALKF QQYVQECADILEWIGDKEAIATSVELGEDWERTEVLHKKFEDFQVELVAKEGRVVEVN QYANECAEENHPDLPLIQSKQNEVNAAWERLRGLALQRQKALSNAANLQRFKRDVTEA IQWIKEKEPVLTSEDYGKDLVASEGLFHSHKGLERNLAVMSDKVKELCAKAEKLTLSH PSDAPQIQEMKEDLVSSWEHIRALATSRYEKLQATYWYHRFSSDFDELSGWMNEKTAA INADELPTDVAGGEVLLDRHQQHKHEIDSYDDRFQSADETGQDLVNANHEASDEVREK MEILDNNWTALLELWDERHRQYEQCLDFHLFYRDSEQVDSWMSRQEAFLENEDLGNSL GSAEALLQKHEDFEEAFTAQEEKIITVDKTATKLIGDDHYDSENIKAIRDGLLARRDA LREKAATRRRLLKESLLLQKLYEDSDDLKNWINKKKKLADDEDYKDIQNLKSRVQKQQ VFEKELAVNKTQLENIQKTGQEMIEGGHYASDNVTTRLSEVASLWEELLEATKQKGTQ LHEANQQLQFENNAEDLQRWLEDVEWQVTSEDYGKGLAEVQNRLRKHGLLESAVAARQ DQVDILTDLAAYFEEIGHPDSKDIRARQESLVCRFEALKEPLATRKKKLLDLLHLQLI CRDTEDEEAWIQETEPSATSTYLGKDLIASKKLLNRHRVILENIASHEPRIQEITERG NKMVEEGHFAAEDVASRVKSLNQNMESLRARAARRQNDLEANVQFQQYLADLHEAETW IREKEPIVDNTNYGADEEAAGALLKKHEAFLLDLNSFGDSMKALRNQANACQQQQAAP VEGVAGEQRVMALYDFQARSPREVTMKKGDVLTLLSSINKDWWKVEAADHQGIVPAVY VRRLAHDEFPMLPQRRREEPGNITQRQEQIENQYRSLLDRAEERRRRLLQRYNEFLLA YEAGDMLEWIQEKKAENTGVELDDVWELQKKFDEFQKDLNTNEPRLRDINKVADDLLF EGLLTPEGAQIRQELNSRWGSLQRLADEQRQLLGSAHAVEVFHREADDTKEQIEKKCQ ALSAADPGSDLFSVQALQRRHEGFERDLVPLGDKVTILGETAERLSESHPDATEDLQR QKMELNEAWEDLQGRTKDRKESLNEAQKFYLFLSKARDLQNWISSIGGMVSSQELAED LTGIEILLERHQEHRADMEAEAPTFQALEDFSAELIDSGHHASPEIEKKLQAVKLERD DLEKAWEKRKKILDQCLELQMFQGNCDQVESWMVARENSLRSDDKSSLDSLEALMKKR DDLDKAITAQEGKITDLEHFAESLIADEHYAKEEIATRLQRVLDRWKALKAQLIDERT KLGDYANLKQFYRDLEELEEWISEMLPTACDESYKDATNIQRKYLKHQTFAHEVDGRS EQVHGVINLGNSLIECSACDGNEEAMKEQLEQLKEHWDHLLERTNDKGKKLNEASRQQ RFNTSIRDFEFWLSEAETLLAMKDQARDLASAGNLLKKHQLLEREMLAREDALKDLNT LAEDLLSSGTFNVDQIVKKKDNVNKRFLNVQELAAAHHEKLKEAYALFQFFQDLDDEE SWIEEKLIRVSSQDYGRDLQGVQNLLKKHKRLEGELVAHEPAIQNVLDMAEKLKDKAA VGQEEIQLRLAQFVEHWEKLKELAKARGLKLEESLEYLQFMQNAEEEEAWINEKNALA VRGDCGDTLAATQSLLMKHEALENDFAVHETRVQNVCAQGEDILNKVLQEESQNKEIS SKIEALNEKTPSLAKAIAAWKLQLEDDYAFQEFNWKADVVEAWIADKETSLKTNGNGA DLGDFLTLLAKQDTLDASLQSFQQERLPEITDLKDKLISAQHNQSKAIEERYAALLKR WEQLLEASAVHRQKLLEKQLPLQKAEDLFVEFAHKASALNNWCEKMEENLSEPVHCVS LNEIRQLQKDHEDFLASLARAQADFKCLLELDQQIKALGVPSSPYTWLTVEVLERTWK HLSDIIEEREQELQKEEARQVKNFEMCQEFEQNASTFLQWILETRAYFLDGSLLKETG TLESQLEANKRKQKEIQAMKRQLTKIVDLGDNLEDALILDIKYSTIGLAQQWDQLYQL GLRMQHNLEQQIQAKDIKGVSEETLKEFSTIYKHFDENLTGRLTHKEFRSCLRGLNYY LPMVEEDEHEPKFEKFLDAVDPGRKGYVSLEDYTAFLIDKESENIKSSDEIENAFQAL AEGKSYITKEDMKQALTPEQVSFCATHMQQYMDPRGRSHLSGYDYVGFTNSYFGN (SEQ ID NO: 68) TMEM79 84283 NM_0323230 Homo sapiens, transmembrane protein 79 (TMEM79), transcript variant 1, mRNA mRNA Sequence AGGTTTTGAGACACAGGTAAAGGGAGGGAGACAGAGAGAAATACTTGCAGAGCCAGCAGGTAGCTGGGCA GCTCCTTCCCGGACGGACGGATGGACAGACGCTGGGGACCCTCCACTCCATATGGAAAGATGACATGACC TTGTGGTAGATCCCAGAACTGAGGCCCCAGGATGACAGAACAGGAGACCCTGGCCCTACTGGAAGTGAAG AGGTCTGATTCCCCAGAGAAGAGCTCACCCCAGGCCTTGGTTCCCAATGGCCGGCAGCCAGAAGGGGAAG GTGGGGCCGAATCCCCGGGAGCTGAGTCCCTCAGAGTGGGGTCTTCAGCTGGATCTCCCACAGCCATAGA GGGGGCTGAGGATGGTCTAGACAGCACAGTAAGTGAGGCTGCCACCTTGCCCTGGGGGACTGGCCCTCAG CCCAGTGCTCCGTTCCCGGATCCCCCTGGCTGGCGGGACATTGAACCAGAGCCCCCTGAGTCAGAACCAC TTACCAAGCTAGAGGAGCTGCCCGAAGACGATGCCAACCTGCTGCCTGAGAAAGCGGCCCGTGCCTTCGT GCCTATTGACCTACAGTGCATTGAGCGGCAGCCCCAAGAAGACCTTATCGTGCGCTGTGAGGCAGGCGAG GGCGAGTGCCGAACCTTCATGCCCCCCCGGGTCACCCACCCCGACCCCACTGAGCGCAAGTGGGCTGAGG CAGTGGTGAGGCCGCCTGGCTGTTCCTGTGGGGGCTGCGGGAGCTGTGGAGACCGTGAGTGGCTAAGGGC TGTGGCCTCCGTGGGAGCCGCACTCATTCTCTTCCCTTGCCTACTATACGGGGCATATGCCTTCCTGCCG TTTGATGTCCCACGGCTGCCCACCATGAGTTCCCGCCTGATCTACACACTGCGCTGCGGGGTCTTTGCCA CCTTCCCCATTGTGCTGGGGATCCTGGTGTACGGGCTGAGCCTGTTATGCTTTTCTGCCCTTCGGCCCTT TGGGGAGCCACGGCGGGAGGTGGAGATCCACCGGCGATATGTGGCCCAGTCGGTCCAGCTCTTTATTCTC TACTTCTTCAACCTGGCCGTGCTTTCCACTTACCTGCCCCAGGATACCCTCAAACTGCTCCCTCTGCTCA CTGGTCTCTTTGCCGTCTCCCGGCTGATCTACTGGCTGACCTTTGCCGTGGGCCGCTCCTTCCGAGGCTT CGGCTACGGCCTGACGTTTCTGCCACTGCTGTCGATGCTGATGTGGAACCTCTACTACATGTTCGTGGTG GAGCCGGAGCGCATGCTCACTGCCACCGAGAGCCGCCTGGACTACCCGGACCACGCCCGCTCGGCCTCCG ACTACAGGCCCCGCCCCTGGGGCTGAGCCTCTCCGCCCTCGCCCTCGGAGTAGGGGGTAGCGGCTTGGGT CTGACACATCTTTGAACCTTGTGGCCAGGCCTGGACTTCGCCCCCAGGCCTAGGACCGCGGTGGGTGGAA CCCTGCTACTGCCCCAACAGGGACTCCAATCAATCGGAGTTCTCCCCTTGCCGGAGCTGCCCTTCACCTT TGGGGCCCGAGACAGTCATAAGGGATGGACTTAGTTTTCTTGCAGGGAAAAAGGTGGACAGCCGTGTTTC TTAAGGATGCTGAGGGCATGGGGCCAGGACCAGGGGAGAGGCACAGCTCCTTCCTGAGCAGCCTCTCACC ACTGCCACAAGGCTCCCTAATGCTGGTCTCTGCTCCACTCCCCGGCTTCCCGTGAGGCAGGAGGCAGAGC CACAGCCAAGGCCCTGACCACTTCTGTGCCAGTTGTCTAAGCAGAGCGCCTCAGGGACGCTGGAAATGCC TTAAGGATAGAGGCTGGGCATCACATCAAATGGGACTGTGGTGTTTGGTGAAAACCTTCCTGAGGATCTG GATTCAGGACCCTCCATGACTGGCCTATTTACTGTTTACAGCTGGCCAGTGCAGAGCTGCTGCTCTTTTA CCTTTTTAGGCCCCTGTAACTTCCCACCTTTAAACTGCCCAGAAGGCATGCCTCTCCCACAGGAAGAGGG GAGCAGACAGGGAAATCTGCCTACCAAGAGGGGTGTGTGTGTCTTTGTGCCCACACGTGGTGGCTGGGGA GTGCCTGGATGGTGCGGTGGTTGATGTTAACCTAGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGT GTGTGTGTGTAACAATAAATTACTACCAGTCAAAAAAAAAAAAAA (SEQ ID NO: 69) Translated protein sequence MTEQETLALLEVKRSDSPEKSSPQALVPNGRQPEGEGGAESPGA ESLRVGSSAGSPTAIEGAEDGLDSTVSEAATLPWGTGPQPSAPFPDPPGWRDIEPEPP ESEPLTKLEELPEDDANLLPEKAARAFVPIDLQCIERQPQEDLIVRCEAGEGECRTFM PPRVTHPDPTERKWAEAVVRPPGCSCGGCGSCGDREWLRAVASVGAALILFPCLLYGA YAFLPFDVPRLPTMSSRLIYTLRCGVFATFPIVLGILVYGLSLLCFSALRPFGEPRRE VEIHRRYVAQSVQLFILYFFNLAVLSTYLPQDTLKLLPLLTGLFAVSRLIYWLTFAVG RSFRGFGYGLTFLPLLSMLMWNLYYMFVVEPERMLTATESRLDYPDHARSASDYRPRP WG (SEQ ID NO: 70) TMIGD2 126259 NM_144615 Homo sapiens transmembrane and immunoglobulin domain containing 2 (TMIGD2), mRNA mRNA Sequence GGAAGTCTGTCAACTGGGAGGGGGAGAGGGGGGTGATGGGCCAGGAATGGGGTCCCCGGGCATGGTGCTG GGCCTCCTGGTGCAGATCTGGGCCCTGCAAGAAGCCTCAAGCCTGAGCGTGCAGCAGGGGCCCAACTTGC TGCAGGTGAGGCAGGGCAGTCAGGCGACCCTGGTCTGCCAGGTGGACCAGGCCACAGCCTGGGAACGGCT CCGTGTTAAGTGGACAAAGGATGGGGCCATCCTGTGTCAACCGTACATCACCAACGGCAGCCTCAGCCTG GGGGTCTGCGGGCCCCAGGGACGGCTCTCCTGGCAGGCACCCAGCCATCTCACCCTGCAGCTGGACCCTG TGAGCCTCAACCACAGCGGGGCGTACGTGTGCTGGGCGGCCGTAGAGATTCCTGAGTTGGAGGAGGCTGA GGGCAACATAACAAGGCTCTTTGTGGACCCAGATGACCCCACACAGAACAGAAACCGGATCGCAAGCTTC CCAGGATTCCTCTTCGTGCTGCTGGGGGTGGGAAGCATGGGTGTGGCTGCGATCGTGTGGGGTGCCTGGT TCTGGGGCCGCCGCAGCTGCCAGCAAAGGGACTCAGGTAACAGCCCAGGAAATGCATTCTACAGCAACGT CCTATACCGGCCCCGGGGGGCCCCAAAGAAGAGTGAGGACTGCTCTGGAGAGGGGAAGGACCAGAGGGGC CAGAGCATTTATTCAACCTCCTTCCCGCAACCGGCCCCCCGCCAGCCGCACCTGGCGTCAAGACCCTGCC CCAGCCCGAGACCCTGCCCCAGCCCCAGGCCCGGCCACCCCGTCTCTATGGTCAGGGTCTCTCCTAGACC AAGCCCCACCCAGCAGCCGAGGCCAAAAGGGTTCCCCAAAGTGGGAGAGGAGTGAGAGATCCCAGGAGAC CTCAACAGGACCCCACCCATAGGTACACACAAAAAAGGGGGGATCGAGGCCAGACACGGTGGCTCACGCC TGTAATCCCAGCAGTTTGGGAAGCCGAGGCGGGTGGAACACTTGAGGTCAGGGGTTTGAGACCAGCCTGG CTTGAACCTGGGAGGCGGAGGTTGCAGTGAGCCGAGATTGCGCCACTGCACTCCAGCCTGGGCGACAGAG TGAGACTCCGTCTCAAAAAAAACAAAAAGCAGGAGGATTGGGAGCCTGTCAGCCCCATCCTGAGACCCCG TCCTCATTTCTGTAATGATGGATCTCGCTCCCACTTTCCCCCAAGAACCTAATAAAGGCTTGTGAAGAAA AAGCAAAAAAAAAAAAAAAAAA (SEQ ID NO: 71) Translated protein sequence MGSPGMVLGLLVQIWALQEASSLSVQQGPNLLQVRQGSQATLVC QVDQATAWERLRVKWTKDGAILCQPYITNGSLSLGVCGPQGRLSWQAPSHLTLQLDPV SLNHSGAYVCWAAVEIPELEEAEGNITRLFVDPDDPTQNRNRIASFPGFLFVLLGVGS MGVAAIVWGAWFWGRRSCQQRDSGNSPGNAFYSNVLYRPRGAPKKSEDCSGEGKDQRG QSIYSTSFPQPAPRQPHLASRPCPSPRPCPSPRPGHPVSMVRVSPRPSPTQQPRPKGF PKVGEE (SEQ ID NO: 72) TUBB6 84617 NM_032525 Homo sapiens tubulin, beta 6 (TUBB6), mRNA mRNA Sequence GGGCACGAGGGCAGAGCCAGTTCCTAGCGCAGAGCCGCGCCCGCCATGAGGGAGATCGTGCACATCCAGG CGGGCCAGTGCGGGAACCAGATCGGCACCAAGTTTTGGGAAGTGATCAGCGATGAGCACGGCATCGACCC GGCCGGAGGCTACGTGGGAGACTCGGCGCTGCAGCTGGAGAGAATCAACGTCTACTACAATGAGTCATCG TCTCAGAAATATGTGCCCAGGGCCGCCCTGGTGGACTTAGAGCCAGGCACCATGGACAGCGTGCGGTCTG GGCCTTTTGGGCAGCTTTTCCGGCCTGACAACTTCATCTTTGGCCAGACGGGTGCAGGGAACAACTGGGC GAAAGGGCACTACACGGAGGGCGCGGAGCTGGTGGACGCAGTGCTGGACGTGGTGCGGAAGGAGTGCGAG CACTGCGACTGCCTGCAGGGCTTCCAGCTCACGCACTCGCTGGGCGGCGGCACGGGCTCAGGCATGGGCA CGCTGCTCATCAGCAAGATCCGTGAGGAGTTCCCGGACCGCATCATGAACACCTTCAGCGTCATGCCCTC GCCCAAGGTGTCGGACACGGTGGTGGAGCCCTACAATGCCACACTGTCGGTGCACCAGCTGGTGGAGAAT ACAGACGAGACCTACTGCATCGACAACGAGGCGCTCTATGACATCTGCTTCCGCACTCTGAAGCTGACAA CGCCCACCTACGGGGACCTCAACCACCTGGTGTCCGCCACCATGAGTGGGGTCACCACCTCGCTGCGCTT CCCGGGCCAGCTCAATGCTGACCTGCGCAAGCTGGCGGTGAACATGGTGCCCTTCCCGCGCCTGCACTTC TTCATGCCTGGCTTCGCGCCGCTCACCAGCCGCGGCAGCCAGCAGTACCGGGCCCTGACCGTGCCCGAGC TCACCCAGCAGATGTTCGACGCCAGGAACATGATGGCCGCCTGCGATCCGCGCCATGGCCGCTACCTGAC CGTGGCCACCGTGTTCCGCGGGCCCATGTCCATGAAGGAGGTGGACGAGCAGATGCTGGCCATCCAGAGT AAGAACAGCAGCTACTTCGTGGAGTGGATTCCCAACAACGTGAAGGTGGCCGTGTGCGACATCCCGCCCC GCGGCCTGAAGATGGCCTCCACCTTCATCGGCAACAGCACGGCCATCCAGGAGCTGTTCAAGCGCATCTC CGAGCAGTTCTCAGCCATGTTCCGGCGCAAGGCCTTCCTGCACTGGTTCACGGGTGAGGGCATGGATGAA ATGGAGTTCACCGAGGCGGAGAGCAACATGAACGACCTGGTATCCGAGTACCAGCAGTACCAGGATGCCA CCGCCAATGACGGGGAGGAAGCTTTTGAGGATGAGGAAGAGGAGATCGATGGATAGTCGGAATAGAGCCG CCCCAACTCAGATCCTACAACACGCAAGTTCCTTCTTGAACCCTGGTGCCTCCTACCCTATGGCCCTGAA TGGTGCACTGGTTTAATTGTGTTGGTGTCGGCCCCTCACAAATGCAGCCAAGTCATGTAATTAGTCATCT GGAACAAAGACTAAAAACAGCAGAGAATTGCGGGTTCTACCCAGTCAGAAGATCACACCATGGAGACTTT CTACTAGAGGACTTGAAAGAGAACTGAGGGGCCACAAAATAAACTTCACCTTCCATTAAGTGTTCAAGCA TGTCTGCAAATTAGGAGGGAGTTAGAAACAGTCTTTTTCATCCTTTGTGATGAAGCCTGAAATTGTGCCG TGTTGCCTTATATGAATATGCAGTATGGGACTTTGAAATAATGATTCATAATAAAATACTAAACGTGTGT CTTCAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 73) Translated protein sequence MREIVHIQAGQCGNQIGTKFWEVISDEHGIDPAGGYVGDSALQL ERINVYYNESSSQKYVPRAALVDLEPGTMDSVRSGPFGQLFRPDNFIFGQTGAGNNWA KGHYTEGAELVDAVLDVVRKECEHCDCLQGFQLTHSLGGGTGSGMGTLLISKIREEFP DRIMNTFSVMPSPKVSDTVVEPYNATLSVHQLVENTDETYCIDNEALYDICFRTLKLT TPTYGDLNHLVSATMSGVTTSLRFPGQLNADLRKLAVNMVPFPRLHFFMPGFAPLTSR GSQQYRALTVPELTQQMFDARNMMAACDPRHGRYLTVATVFRGPMSMKEVDEQMLAIQ SKNSSYFVEWIPNNVKVAVCDIPPRGLKMASTFIGNSTAIQELFKRISEQFSAMFRRK AFLHWFTGEGMDEMEFTEAESNMNDLVSEYQQYQDATANDGEEAFEDEEEEIDG (SEQ ID NO: 74) TYROBP 7305 NM_198125 Homo sapiens TYRO protein tyrosine kinase binding protein (TYROBP), transcript variant 2, mRNA mRNA Sequence AGACTTCCTCCTTCACTTGCCTGGACGCTGCGCCACATCCCACCGGCCCTTACACTGTGGTGTCCAGCAG CATCCGGCTTCATGGGGGGACTTGAACCCTGCAGCAGGCTCCTGCTCCTGCCTCTCCTGCTGGCTGTAAG TGGTCTCCGTCCTGTCCAGGCCCAGGCCCAGAGCGATTGCAGTTGCTCTACGGTGAGCCCGGGCGTGCTG GCAGGGATCGTGATGGGAGACCTGGTGCTGACAGTGCTCATTGCCCTGGCCGTGTACTTCCTGGGCCGGC TGGTCCCTCGGGGGCGAGGGGCTGCGGAGGCGACCCGGAAACAGCGTATCACTGAGACCGAGTCGCCTTA TCAGGAGCTCCAGGGTCAGAGGTCGGATGTCTACAGCGACCTCAACACACAGAGGCCGTATTACAAATGA GCCCGAATCATGACAGTCAGCAACATGATACCTGGATCCAGCCATTCCTGAAGCCCACCCTGCACCTCAT TCCAACTCCTACCGCGATACAGACCCACAGAGTGCCATCCCTGAGAGACCAGACCGCTCCCCAATACTCT CCTAAAATAAACATGAAGCACAAAAACAAAAAAAAAAAAAAAAAA (SEQ ID NO: 75) Translated protein sequence MGGLEPCSRLLLLPLLLAVSGLRPVQAQAQSDCSCSTVSPGVLA GIVMGDLVLTVLIALAVYFLGRLVPRGRGAAEATRKQRITETESPYQELQGQRSDVYS DLNTQRPYYK (SEQ ID NO: 76) YTHDF1 54915 NM_017798 Homo sapiens YTH domain family, member 1 (YTHDF1), mRNA mRNA Sequence GCGTGCACGCTGACGCCGCGCAGTCTCGTCCCCTGCCGCCGCCGTCGCCGCTGCTGTCGCCGCCGCCGCC GCCATTGGAGTCGACGCCTCCTCAGTGCGTCCGCGTCCCGGGCTCACCGCCGCTGCCGCCTCGCCAGGGG CCCGCGCGCCCAGCAGCCGCCGCCGCCGCCCGGCCGGCGCCCGGGGAATTGGCGGCGGGGCCCGGGGCCG CGCGAGCTAGGGTGACAGGCCCGGCCTCTAGGGGAGGCCCGAGCCGGCGGGCGCCCCGGCCCCGCGTCTA GTTGTTCATGAAGCATGTCGGCCACCAGCGTGGACACCCAGAGAACAAAAGGACAAGATAATAAAGTACA AAATGGTTCGTTACATCAGAAGGATACAGTTCATGACAATGACTTTGAGCCCTACCTTACTGGACAGTCA AATCAGAGTAACAGTTACCCCTCAATGAGCGACCCCTACCTGTCCAGCTATTACCCGCCGTCCATTGGAT TTCCTTACTCCCTCAATGAGGCTCCGTGGTCTACTGCAGGGGACCCTCCGATTCCATACCTCACCACCTA CGGACAGCTCAGTAACGGAGACCATCATTTTATGCACGATGCTGTTTTTGGGCAGCCTGGGGGCCTGGGG AACAACATCTATCAGCACAGGTTCAATTTTTTCCCTGAAAACCCTGCGTTCTCAGCATGGGGGACAAGTG GGTCTCAAGGTCAGCAGACCCAGAGCTCCGCGTATGGGAGCAGCTACACCTACCCCCCGAGCTCCCTGGG TGGCACGGTGGTTGATGGGCAGCCAGGCTTTCACAGCGACACCCTCAGCAAGGCCCCCGGGATGAACAGC CTGGAGCAGGGCATGGTTGGCCTGAAGATTGGGGACGTCAGCTCCTCCGCCGTCAAGACGGTGGGCTCTG TCGTCAGCAGCGTGGCACTGACTGGTGTCCTTTCTGGCAACGGTGGGACAAATGTGAACATGCCAGTTTC AAAGCCGACCTCGTGGGCTGCCATTGCCAGCAAGCCTGCAAAACCACAGCCTAAAATGAAAACAAAGAGC GGGCCTGTCATGGGGGGTGGGCTGCCCCCTCCACCCATAAAGCATAACATGGACATTGGCACCTGGGATA ACAAGGGGCCTGTGCCGAAGGCCCCAGTCCCCCAGCAGGCACCCTCTCCACAGGCTGCCCCACAGCCCCA GCAGGTGGCTCAGCCTCTCCCAGCACAGCCCCCAGCTTTGGCTCAACCGCAGTATCAGAGCCCTCAGCAG CCACCCCAGACCCGCTGGGTTGCCCCACGCAACAGAAACGCGGCGTTTGGGCAGAGCGGAGGGGCTGGCA GCGATAGCAACTCTCCTGGAAACGTCCAGCCTAATTCTGCCCCCAGCGTCGAATCCCACCCCGTCCTTGA AAAACTGAAGGCTGCTCACAGCTACAACCCGAAAGAGTTTGAGTGGAATCTGAAAAGCGGGCGTGTGTTC ATCATCAAGAGCTACTCTGAGGACGACATCCACCGCTCCATTAAGTACTCCATCTGGTGTAGCACAGAGC ACGGCAACAAGCGCCTGGACAGCGCCTTCCGCTGCATGAGCAGCAAGGGGCCCGTCTACCTGCTCTTCAG CGTCAATGGGAGTGGGCATTTTTGTGGGGTGGCCGAGATGAAGTCCCCCGTGGACTACGGCACCAGTGCC GGGGTCTGGTCTCAGGACAAGTGGAAGGGGAAGTTTGATGTCCAGTGGATTTTTGTTAAGGATGTACCCA ATAACCAGCTCCGGCACATCAGGCTGGAGAATAACGACAACAAACCGGTCACAAACTCCCGGGACACCCA GGAGGTGCCCTTAGAAAAAGCCAAGCAAGTGCTGAAAATTATCAGTTCCTACAAGCACACAACCTCCATC TTCGACGACTTTGCTCACTACGAGAAGCGCCAGGAGGAGGAGGAGGTGGTGCGCAAGGAACGGCAGAGTC GAAACAAACAATGAGGGCGAACCAGTTTCTTACATGTTCTAACGTTTGACTTTGAAAACAGTTTAAAACA CGTGTGCTTGGTCAGCTCCAGTGTGTCGTCCCGTGCGGGGGTTGAGTGTTGCATCTTTGCCTTTCTTGTC GTTGATTTTTGCCCAGATGGATCTGCATTTATTTGTACTTTTTCTATGTATTATAATCCTGTAGAAGTCA CTAATAAAGGAGTATTTTTTTTGTCAGCTTATCAATCAGACTGATCTAATGTGAAATGTAAGTATCCTTA AAAACAAAGCATCTATTTTGGCAGAAATTGTGTTCTTAAATTCAGTCATTTGATATTCTGTGAGACTTCA TATTTCTCATCCCTTTATTGCTTTTTAGCAAACATAAGAAACCATGAGTCATTTTGTCATTTAGAGTATT CTGATAAAATCTCTTGAAAATACTGAAATCAAAAGGTTAATGATTTTTTGTTCATTCTGATTTGTCATTT TATTATCTGTTATCGGTCTAAAGTGCTAATTTACCCATTTGATTTTTCTGCTAGACAGATAACTTTTAAT TTTTCAAATTTGGCAGACACTTTTTTTTTTTTTTTGAAAATCTTTCCTTCCAGATCTGTTGCCCACTGAA CAGCCACCCGTCCCTCACTGTCCTGGTGTCCGATTGGGCTGGATGGTGTTGGGGCATGATGTGTGGAGGA ACTGGAAGGTGCTTTAGGTCTGGTTCAGGGTCGGGCATTCTTTGTTGTTTGCACATCTTTTTAAATTTTA CACCTTTTCTTAAGAATTCTAATGCCGTCTTAAGTTTTTATACCAATAATGCTGAGCTTTAAGTGTAGGA TCTGGTAGTACAGACAGTGTGATGGATGATGCTGCTGGTTGTAAATTTCATCGTGTGTGTCTAATTTTTT TTCCTGTTGAATGGGTAAAAACAAAACAAAACTTTTTTTAGAAGATGAATTTGCTGTCATGTTTTGTGGA ATGAGGGACCGTTGAGCTCACTACCACCTGGAGTTTGAGTTGAAGCATGAAAATGGTGCCCATGCCTGAC GCTCCAGCGCCTGGATCTGCACGTGCCCTTGTAGAGGATCCTTACCGTCCTAGAGAGCAGACGCTTTCTG AAAACTACTTGCTCCAAAAGACCCTCTGAGTTAACGTTTCAGCTGTATCATTAGACTTGTATTTAGAGCG TGTCACTTCCTCTGAACTGTTACTGCCTGAATGGAGTCCTGGACGACATTGGGTTTTTCCTCTAGGAGAA TACAAGCCTTAATAAACAATACTATTTAGCAAAAAAAAAAAAAAAAAAAAAAAAAAA (SEQ ID NO: 77) Translated protein sequence MSATSVDTQRTKGQDNKVQNGSLHQKDTVHDNDFEPYLTGQSNQ SNSYPSMSDPYLSSYYPPSIGFPYSLNEAPWSTAGDPPIPYLTTYGQLSNGDHHFMHD AVFGQPGGLGNNIYQHRFNFFPENPAFSAWGTSGSQGQQTQSSAYGSSYTYPPSSLGG TVVDGQPGFHSDTLSKAPGMNSLEQGMVGLKIGDVSSSAVKTVGSVVSSVALTGVLSG NGGTNVNMPVSKPTSWAAIASKPAKPQPKMKTKSGPVMGGGLPPPPIKHNMDIGTWDN KGPVPKAPVPQQAPSPQAAPQPQQVAQPLPAQPPALAQPQYQSPQQPPQTRWVAPRNR NAAFGQSGGAGSDSNSPGNVQPNSAPSVESHPVLEKLKAAHSYNPKEFEWNLKSGRVF IIKSYSEDDIHRSIKYSIWCSTEHGNKRLDSAFRCMSSKGPVYLLFSVNGSGHFCGVA EMKSPVDYGTSAGVWSQDKWKGKFDVQWIFVKDVPNNQLRHIRLENNDNKPVTNSRDT QEVPLEKAKQVLKIISSYKHTTSIFDDFAHYEKRQEEEEVVRKERQSRNKQ (SEQ ID NO: 78) Z1C5 85416 NM_033132 Homo sapiens Zic family member 5 (odd-paired homolog, Drosophila) (ZIC5), mRNA mRNA Sequence GCGGCCGCAAGCACGGGGGCGAATCCCCGCTGGGTCGAGGGCCTGAACGGGAGCCAATCGAGCAGCCGAG GCTACTGCCAATCACGCGGCTCCCTCCAATCCCACCCGTGCCATTTCCAAAATCTCGGTCCCACTGTGCA GCTCAAATGTGGTGTTCACTCTGCCAATCGCTGGAGGATAGAGTGGGAACAGGAATAAGCAGAGTTAAGA GGCCAGGACAAAAGAAGTTAAAGAGCGCCCAATACATACATGTTTTTGAAGGCGGGCAGAGGGAATAAAG TCCCCCCAGTGAGGGTCTATGGGCCTGATTGTGTAGTTCTGATGGAGCCCCCTTTGAGCAAGAGGAACCC GCCAGCGCTGAGATTAGCGGATTTGGCAACGGCTCAGGTCCAGCCGCTTCAGAATATGACAGGCTTCCCG GCGCTGGCCGGCCCGCCCGCCCACTCCCAACTCCGGGCCGCCGTCGCGCACCTCCGCCTGCGGGACCTGG GCGCTGACCCCGGCGTGGCCACCACTCCGCTCGGACCCGAGCACATGGCCCAGGCGAGCACGCTGGGCCT CAGCCCTCCCTCCCAGGCGTTCCCGGCACACCCGGAGGCTCCGGCAGCCGCCGCCCGTGCTGCAGCCTTG GTCGCGCACCCCGGCGCGGGCAGCTACCCCTGCGGCGGGGGCAGCAGTGGCGCGCAGCCCTCCGCGCCCC CGCCCCCAGCCCCTCCTCTTCCTCCCACCCCTTCACCCCCTCCCCCTCCCCCGCCTCCTCCTCCTCCTGC CCTCTCGGGCTACACCACCACCAACAGTGGCGGCGGCGGCAGCAGCGGCAAAGGCCACAGCAGGGACTTC GTCCTCCGGAGGGACCTTTCCGCCACGGCCCCCGCGGCGGCCATGCACGGGGCCCCGCTCGGAGGGGAGC AGCGGTCCGGCACCGGCTCCCCCCAGCACCCGGCCCCGCCTCCCCACTCGGCCGGCATGTTCATCTCCGC CAGCGGCACCTACGCGGGCCCGGACGGCAGCGGCGGCCCGGCGCTCTTCCCCGCGCTGCACGACACGCCG GGGGCCCCAGGCGGCCACCCGCACCCGCTCAACGGCCAGATGCGCCTGGGGCTGGCGGCGGCAGCGGCAG CCGCGGCGGCTGAGCTGTACGGCCGCGCCGAACCGCCCTTCGCGCCGCGCTCTGGGGACGCGCACTACGG GGCGGTTGCGGCCGCAGCGGCGGCCGCCCTGCACGGCTACGGAGCCGTGAACTTAAACCTGAACCTGGCG GCTGCGGCGGCCGCAGCAGCGGCCGGGCCCGGGCCCCACCTGCAGCACCACGCGCCGCCCCCGGCGCCGC CGCCGCCGCCGGCGCCCGCGCAGCACCCGCACCAGCACCACCCCCACCTCCCAGGGGCGGCTGGGGCCTT CCTGCGCTACATGCGGCAGCCAATCAAGCAGGAGCTCATCTGCAAGTGGATCGACCCCGACGAGCTGGCC GGGCTGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCGCCACCGCCCCCGGCCGGCGGCGCCAAGCCCT GCTCCAAAACTTTCGGCACCATGCACGAGCTGGTGAATCACGTCACGGTGGAGCACGTGGGAGGCCCCGA GCAGAGCAGCCACGTCTGCTTCTGGGAGGACTGTCCGCGCGAGGGCAAGCCCTTCAAGGCCAAATACAAG CTCATCAACCACATCCGCGTGCACACCGGCGAGAAGCCCTTTCCCTGCCCTTTCCCCGGCTGCGGCAAGG TCTTCGCGCGCTCCGAGAACCTCAAGATCCACAAGCGTACTCATACAGGGGAAAAGCCTTTCAAATGTGA ATTTGATGGCTGTGACAGGAAGTTTGCCAATAGCAGTGATCGGAAGAAACATTCCCATGTCCACACCAGT GACAAGCCCTACTACTGCAAGATTCGAGGCTGTGACAAATCCTACACTCACCCAAGCTCCCTGAGGAAGC ACATGAAGATTCACTGCAAGTCCCCGCCACCTTCTCCAGGACCCCTTGGTTACTCATCAGTGGGGACTCC AGTGGGCGCCCCCTTGTCCCCTGTGCTGGACCCAGCCAGGAGTCACTCCAGCACTCTGTCCCCTCAGGTG ACCAACCTCAATGAGTGGTACGTTTGCCAGGCCAGTGGGGCCCCCAGCCACCTCCACACCCCTTCCAGCA ACGGAACCACCTCTGAGACTGAAGATGAGGAAATTTACGGGAACCCTGAAGTTGTGCGGACGATACATTA GAATTTATTATTAATAATAATAAGTGAAATAATAAGTGGGAGTCCTTGGACCACATCCTAACCTGAGACA ATGCCGAGCCTGAGACAAACCCGTGACTCAGACTTGCCACCGGGTCTAATTAGCCCTATTTATTCAGTAT GAAACCCTATGGTGTTTGTACATTTAATTAATTTAATTAAGATATTTGGGCTTTTTTTTTTTTTTTTCTT AAAAAACAAACAAAAAACAACCAAGCTGGACTTGTACATTGCAGGAGGATGGGGCTGGGGGCAAATTGTA CCAAGGAAAATGAATGGAGAGATTAGTTAATGGCGATACACACTGCCGATGCAATATATATATATATATA TATATACATATATATATATATTATTTTTTTTAAAAGGGGGAGAAAAAGAGCATTAAGTCAGAACTTAACA CAGCACCAAGGCCCTCTGCATTTCCCAGAGTGCCTCTCAAATGCCTTTGACACCATACCATGGGCTGCTT TTGAGCCTCCTTGTTGGACCCTAATTCTGCCAAGGCCTCTTGATTGTAAACCACACACCTGCTGCATTGC CAACAGATCCTGTTCCGTACCTGTGTCCAAAAACATTTGTAAAAACCCTTTGAGTTTAATATTTGTAATT TTTAATTTCCACTCTTTTATTACTGATCTTAGCTTAATACAATATTTTTATACAGGATTATTTCTTCAGT ATCCTACTGTGTGATTTTAAAAAAAGATGCAGCAACCTTAATATATCTCCATATCTTGTGCTACTGTGAT TGTTCAAGCAAAAGTGGAGAGAAGAAAAGCTGCTGCAAAAGACAACTGTGAAACTGTGATATTTTATAAA ATAGAAGAAATTCAAGTGCTTTCTTTTTCCTATATGTTTTTTTTTTTTTATCTGAATTCTCAGATACTGC CTCCTAACTGTGTCCAAACTTCTTGTGTAATAAAGAGATTCTGTTTTCGATCCTAAGTTCTTTGGGATGC CAACATTCACAGTCAAGTCTTGAGGAGGTGTGATGATGGCATCATGCCTATTTTTTTGGAAAGCTGTTGT TTTTAAAACAGGCCAACACCTCTTTTATACTGTTGTATCAGCCTTTTAAAAAGTCTATTTTTCAATGCCT GAAACTGCATTTTAATGCATTTTCTTCCACCTGAGCACTGAGCACACCAAACTGGAATCCATTTGAAAAT GACAGTGTGTGAAGTGTATGATTTACATTAAAAGAGGGGAGGGAGTTGCCATACATATTAAAAATTTTTA AAAGGTTTATAGTTACCACCAAACACTGATGAATGTGTGACCTTTGCCAGAGCTGTCAAGCTAGGATAAA AAAGGTCAAGGACCTAGGACAATAACTCTTAGTCGATTTATTTTCGGTTGGTACAACACATCTCCTGTGC AAAATGTAGTCCATCAGAAACATCCTACAGATACACTAAAGAGCACTAATTTATCCTTAGAGACCCCGAA GACACCCCCTCCCCAGGGTTTGTAGAAATTTGTTTTGTGTGCTGTGAGTGGTTGATGTAGTCTTGTCATT GTTAATAACTTGTATGTGAACACTATTATTTGTACAGTTGAATTAATTTATTTTCAGACATCATCCTTTT TTTTTTTCTTTCCTGGAAGAGTTCAAAGCACACCAAAGAATTATATTATACATTTTGGTGAAAGATTGTC ATTTATGATCCATGGTTTATTTAAAAAAAAAAGGAAAGAAAATGGAAAAATATATTTTTAAGCTTACTTG AATGAACAACGTAATGTGAAAACCAAGACTCTTCCTGCATGTCTTTTTTGCATTGTGTTGATAAGATTAT ATATAGTTTATAGATATATTATATTACTAGTACAGTGCATGGTGCTGTCACTTGGAAAGCCTTTCAATGT TGTCTTCAGATTGTTGTGATGAATATGAAACATGCAGACCCTCCTTTATAAAGAAAAAGACCTTAAAACT TGAATATGAGATAATTTTACATTTTAAAAGTTTATTTGATTTTCATATTATTCACTTTCAAAGCCCTTTC AAATAGAAAAGGTATGAACTTTTGGGGGGATAATTTATGTATCGTAAACTTATTAGAACAAAATATTCCT GATGTATAATGAGTTGTTTTATTTATACAACTTTTTCAATGGTAGTTTGCACTATTCTTTATTATGCTAC AGGTTTATTTATTATGAAACAAAGGAATATGTATTTTATGTATTTTACCATGCATAGGTTAACTCTTTGC CACAGATTTATTGGTTCTTGATACACCTAAAATAAAAAAAAATGTGTACCTCCAATAGAGAGCAAGCAAG AATGATTATGAAGTAACAAATTTAATAAAGGTATTCTTGTTATTATTAAAAAAAAAA (SEQ ID NO: 79) Translated protein sequence MFLKAGRGNKVPPVRVYGPDCVVLMEPPLSKRNPPALRLADLAT AQVQPLQNMTGFPALAGPPAHSQLRAAVAHLRLRDLGADPGVATTPLGPEHMAQASTL GLSPPSQAFPAHPEAPAAAARAAALVAHPGAGSYPCGGGSSGAQPSAPPPPAPPLPPT PSPPPPPPPPPPPALSGYTTTNSGGGGSSGKGHSRDFVLRRDLSATAPAAAMHGAPLG GEQRSGTGSPQHPAPPPHSAGMFISASGTYAGPDGSGGPALFPALHDTPGAPGGHPHP LNGQMRLGLAAAAAAAAAELYGRAEPPFAPRSGDAHYGAVAAAAAAALHGYGAVNLNL NLAAAAAAAAAGPGPHLQHHAPPPAPPPPPAPAQHPHQHHPHLPGAAGAFLRYMRQPI KQELICKWIDPDELAGLPPPPPPPPPPPPPPPAGGAKPCSKTFGTMHELVNHVTVEHV GGPEQSSHVCFWEDCPREGKPFKAKYKLINHIRVHTGEKPFPCPFPGCGKVFARSENL KIHKRTHTGEKPFKCEFDGCDRKFANSSDRKKHSHVHTSDKPYYCKIRGCDKSYTHPS SLRKHMKIHCKSPPPSPGPLGYSSVGTPVGAPLSPVLDPARSHSSTLSPQVTNLNEWY VCQASGAPSHLHTPSSNGTTSETEDEEIYGNPEVVRTIH (SEQ ID NO: 80) 

What is claimed is:
 1. A method of treating a subject having breast cancer, the method comprising assaying a breast cancer sample derived from said subject to determine the level of expression in said sample of at least one biomarker selected from the group of biomarkers listed in Table 1, detecting no expression or a low level of expression of said at least one biomarker in said sample relative to a normal control; and administering a therapeutically effective amount of eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof, to said subject.
 2. The method of claim 1, wherein the pharmaceutically acceptable salt of eribulin is eribulin mesylate.
 3. The method of claim 1, wherein said subject has not been previously treated with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof.
 4. The method of claim 1, wherein said subject has been previously treated with eribulin, an analog thereof, or a pharmaceutically acceptable salt thereof.
 5. The method of claim 1, wherein said breast cancer is an Estrogen Receptor (ER) negative breast cancer, a Progesterone Receptor (PR) negative breast cancer, and/or a HER-2 negative breast cancer.
 6. The method of claim 1, wherein at least 2, 3, 4 or 5 biomarkers selected from the group of biomarkers listed in Table 1 have a low level of expression.
 7. The method of claim 1, wherein there is a low level of expression of said biomarker as compared to a control.
 8. The method of claim 7, where said biomarker is not expressed at a detectable level.
 9. The method of claim 1, wherein the level of expression of said biomarker is determined at the nucleic acid level.
 10. The method of claim 9, wherein the level of expression of said biomarker is determined by detecting cDNA, mRNA, miRNA or DNA.
 11. The method claim 9, wherein the level of expression of said biomarker is determined by using a technique selected from the group consisting of polymerase chain reaction (PCR) amplification reaction, reverse-transcriptase PCR analysis, quantitative reverse-transcriptase PCR analysis, Northern blot analysis, RNAase protection assay, digital RNA detection/quantitation, and combinations or subcombinations thereof.
 12. The method of claim 1, wherein the level of expression of said biomarker is determined at the protein level.
 13. The method of claim 12, wherein the presence of the protein is detected using an antibody or antigen binding fragment thereof, which specifically binds to the protein.
 14. The method of claim 13, wherein the antibody or antigen binding fragment thereof is selected from the group consisting of a murine antibody, a human antibody, a humanized antibody, a bispecific antibody, a chimeric antibody, a Fab, Fab′, F(ab′)₂, ScFv, SMIP, affibody, avimer, versabody, nanobody, a domain antibody, and an antigen binding fragment of any of the foregoing.
 15. The method of claim 13, wherein the antibody or antigen binding fragment thereof is labeled.
 16. The method of claim 15, wherein the antibody or antigen binding fragment thereof is labeled with a label selected from the group consisting of a radio-label, a biotin-label, a chromophore-label, a fluorophore-label, and an enzyme-label.
 17. The method of claim 12, wherein the level of expression of said biomarker is determined by using a technique selected from the group consisting of an immunoassay, a western blot analysis, a radioimmunoassay, immunofluorimetry, immunoprecipitation, equilibrium dialysis, immunodiffusion, electrochemilummescence immunoassay (ECLIA), ELISA assay, immunopolymerase chain reaction and combinations or sub-combinations thereof.
 18. The method of claim 17, wherein the immunoassay is (a) a solution-based immunoassay selected from the group consisting of electrochemilumninescence, chemiluminescence, fluorogenic chemiluminescence, fluorescence polarization, and time-resolved fluorescence; or (b) a sandwich immunoassay selected from the group consisting of electrochemiluminescence, chemiluminescence, and fluorogenic chemilumninescence.
 19. The method of claim 1, wherein said sample is selected from the group consisting of a fluid, or component thereof, obtained from said subject, blood, lymph, serum, plasma, cystic fluid, nipple aspirates, urine, sputum, fluid collected from a biopsy, a tissue, or component thereof, obtained from said subject, breast tissue, connective tissue, lymphatic tissue, tissue obtained from a biopsy, tissue obtained from a lump biopsy, breast tissue cells, and circulating breast tumor cells.
 20. The method of claim 1, wherein said subject is a human subject. 